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Chronobiology International
The Journal of Biological and Medical Rhythm Research
Volume 10, 1993 - Issue 1
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Review Article

The Circadian System of Crustaceans

Hugo Aréchiga Departamento de Fisiología. Biofisica y Neurociencias, Centro de Investigatión y de Estudios Avanzados del IPN, Colima, México
,
Fernando Fernéndez-Quiróz Departamento de Fisiología. Biofisica y Neurociencias, Centro de Investigatión y de Estudios Avanzados del IPN, Colima, México
,
Francisco Fernéndez de Miguel Departamento de Fisiología. Biofisica y Neurociencias, Centro de Investigatión y de Estudios Avanzados del IPN, Colima, México
&
Leonard Rodríguez-Sosa Departamento de Fisiología. Biofisica y Neurociencias, Centro de Investigatión y de Estudios Avanzados del IPN, Colima, México
Pages 1-19 | Received 20 Sep 1991, Accepted 27 Jan 1992, Published online: 07 Jul 2009

References

  • Page TL. Neural and endocrine control of circadian rhythmicity in invertebrates. Handbook of behavioral neurobiology, J Aschoff. Plenum Press, New York 1981; 145–81
  • De Coursey P. Biological timing. Biology of Crustacea, J Vernberg, WB Vernberg. Academic Press, New York 1983; vol. 7: 107–61
  • Palmer JD. Contributions made to chronobiology by studies of fiddler crab rhythms. Chronobiol Int 1991; 8: 110–30
  • Aréchiga Naylor HE. Endogenous factors in the control of rhythmicity in decapod crustaceans. Biological rhythms in the marine environment, PJ de Coursey. University of South Carolina Press, Columbia, South Carolina 1976; 1–16
  • Dowse HB, Ringo JM. The search for hidden periodicities in biological time series revisited. J Neuro-biol 1989; 139: 487–515
  • Brown FA. Physiological rhythms. The physiology of crustacea, TH Waterman. Academic Press, New York 1961; 401–30
  • Aréchiga H, Wiersma C AG. Circadian rhythm of activity in the crayfish visual units. J Nrirrobiol 1969; 1: 71–85
  • Aréchiga H, Fuentes B, Barrera B. Circadian rhythm of responsiveness in the visual system of the crayfish. Neurobiology of invertebrates, J Salanki. Publishing House of the Hungarian Academy of Sciences, Budapest 1973; 403–26
  • Fernández de Miguel F, Aréchiga H. Entrainment by food of circadian locomotor activity rhythm in the crayfish. Soc Neurosci Abstr 1988; 14: 1299
  • Page T, Larimer L JL. Entrainment of the circadian locomotor activity rhythm in the crayfish. J Comp Physiol 1972; 78: 107–20
  • Naylor E, Atkinson R JA. Entrainment of a tidal rhythm by hydrostatic pressure. The, effects of pressure on living organisms, M Sleigh, G Alister. Academic Press, New York 1972; 395–415
  • Naylor E, Williams BG. Effects of eyestalk removal on rhythmic locomotor activity in Curcinus. J Exp Biol 1968; 49: 107–16
  • Webb HM. Diurnal variations in response to light in the fiddler crab. Uca. Physiol Zool 1950; 23: 310–37
  • Stevens GC. Influence of temperature fluctuations on the diurnal melanophore rhythm of the fiddler crab. Ucu. Physiol Zool 1957; 30: 55–69
  • Enright JT. Resetting a tidal clock: a phase-response curve for Exciroluna. Biological rhythms in the environment, PJ De Coursey. University of South Carolina Press, Columbia, South Carolina 1976; 103–14
  • Naylor E, Williams BG. Phase-responsiveness of the circatidal locomotor activity rhythm of Hemi-grupsirs edwardsi (Hilgendorg) to simulated high tide. J Murine Biol Assoc UK 1984; 64: 81–150
  • Brown F, Webb A HM. Temperature relations of an endogenous daily rhythmicity in the fiddler crab. Uca. Physiol Zool 1948; 21: 271–81
  • Stevens GC. Responses of the diurnal melanophore rhythm of Uca pugnax to changes in temperature. Biol Bull 1955; 109: 352
  • Palmer JD. Comparative studies of circadian locomotory rhythms in four species of terrestrial crabs. Am Middl Nat 1971; 85: 97–107
  • Fuentes-Pardo B, Inclán-Rubio V. Correlation between motor and electroretinographic circadian systems in the crayfish Procutnbarus bouvieri (Ortmann). Comp Biochem Physiol 1981; 68A: 477–85
  • Palmer J, Williams D BG. Comparative studies of tidal rhythms. III. Spontaneous splitting of the peaks of crab locomotory rhythms. Murine Behav Physiol 1987; 13: 63–75
  • Reid D, Naylor GE. Entrainment of bimodal circatidal rhythms in the shore crab Carcinus maenas. J Biol Rhythms 1990; 5: 333–47
  • Brown FA, Jr, Webb M. Studies of the daily rhythmicity of the fiddler crab Uca. Modifications by light. Physiol Zool 1949; 22: 136–48
  • Kalmus H. über einen latenten physiologischen Farbwechel beim Flusskrebses, Potamobius astacus, sowie seine hormonale Beeinflussung. Z vergleich Physiol 1938; 25: 784–97
  • Kalmus H. Das Aktogram des Flusskrebses und seine Beeinflussung durch organextrakte. Z vergleich Physiol 1938; 25: 798–802
  • Webb H, Bennett MF, Brown FA. Persistence of an endogenous diurnal rhythmicity in eyestalkless Uca pugilator. Biol Bull 1954; 106: 371–7
  • Aréchiga H, Huberman A, Naylor E. Hormonal modulation of circadian neural activity in the crab Carcinus maenas (L.). Proc Roy Soc Lond B 1974; 187: 299–313
  • Bennitt R. Diurnal rhythm in the proximal cells of the crayfish retina. Physiol Zool 1932; 5: 65–9
  • Welsh J. Diurnal rhythm of the distal pigment cells in the eyes of certain crustaceans. Proc Nat Acud Sci USA 1930; 16: 386–95
  • Aréchiga H. Modulation of visual input in the crayfish. Identified neurons and bihvior in arthropods, G Hoyle. Plenum Press, New York 1977; 387–403
  • Brycesson KP. Diurnal changes in photoreceptor sensitivity in a reflecting superposition eye. J Comp Physiol A 1986; 158: 573–82
  • Olivo R, Larsen ME. Brief exposure to light initiates screening pigment migration in the retinula cells of the crayfish Procambarus. J Comp Phiysiol 1978; 125A: 91–6
  • Frixione E, Aréchiga H, Tsutsumi V. Photomechanical migrations of pigment granules along the retinula cells of the crayfish. J Neurobiol 1979; 10: 573–90
  • Fernlund P. Structure of a light-adapting hormone from the shrimp Puridalus borealis. Biochem Biophys Acta 1976; 439: 17–25
  • Fernlund P, Josefsson L. Crustacean color change hormone: aminoacid sequence and chemical synthesis. Science 1972; 177: 173–5
  • Rodríguez-Sosa L. Rho circádico de neurosecreción en el tallo ocular del crustáceo decápodo.[Dissertation]. CINVESTAV-IPN, México 1989
  • Rodríguez-Sosa L, Aréchiga H. Range of modulation of light sensitivity by accessory pigments in the crayfish compound eye. Vision Res 1982; 22: 1515–24
  • Sánchez Fuentes- J, Pardo B. Circadian rhythm in the amplitude of the electroretinogram in the isolated eyestalk of the crayfish. Comp Biochrm Physiol 1977; 56A: 601–9
  • Noguerón I, Aréchiga H. Ritmo circádico de sensibilidad a la luz en la retina aislada del acocil. Bol Estud Med Bid Mex 1987; 35: 165
  • Black JB, Huner JZ. A silver eyed mutant in the crayfish Procambarus clurkii (Girard). Assoc SE Biol Bull 1976; 23: 44
  • Wiersma C AG, Roach J, Glantz RM. Neural integration in the optic system. The biology of Crustacea, DE Bliss, DC Sandeman, HL Atwood. Academic Press, New York 1982; vol. 4: 1–31
  • Aréchiga H, Bañuelos E, Frixione E, Picones A, Rodríguez-Sosa L. Modulation of crayfish retinal sensitivity by 5-hydroxytryptamine. J Exp Biol 1990; 150: 123–43
  • Aréchiga H, Huberman A. Hormonal control of circadian rhythmicity in crustaceans. Frontiers in hormone rescurch, H Aréchiga, C Valverde. Karger, Basel 1980; vol. 6.: 16–34
  • Hamman A. Die neuroendokrine steverung tagesrhythmischer blutzuckerschwankungen durch die sinusdruse beim flusskrebs. J Comp Physiol 1974; 89: 197–214
  • Keller R. Purification and aminoacid composition of the hyperglycaemic neurohormone from the sinus gland of Orconectes limosus and comparison with the hormone from Carcinus maenas. J Comp Physiol 1981; 141: 445–50
  • Aréchiga H, Mena F. Circadian variations of hormonal content in the nervous system of the crayfish. Comp Biochem Physiol 1975; 52A: 581–4
  • Rodríguez-Sosa L, Calderón J, Hernández J, Aréchiga H. The isolated eyestalk of the crayfish maintains a circadian rhythm of neurosecretion content in the crayfish eyestalk. Soc Neurosci Abstr 1990; 16: 909
  • Aréchiga H, Cortés JL, García U, Rodríguez Sosa L. Neuroendocrine correlates of circadian rhythmic-ity in crustaceans. Amer Zool 1985; 25: 265–74
  • Williams JA, Pullin R SV, Naylor E, Smith G, Williams BG. The role of Hanstroms organ in clock control in Carcinus macnas. Cyclic phenomena in marine plants and animals, E Naylor, RG Hartnoll. Pergamon Press, Oxford 1979; 459–66
  • Aréchiga H, García U, Rodríguez-Sosa L. Neurosecretory role of crustacean eyestalk in the control of neuronal activity. Model neural networks and behavior, AL Selverston. Plenum Press, New York 1985; 361–79
  • Dircksen H, Webster SG, Keller R. Immunocytochcmical demonstration of the neurosecretory systems containing putative moult-inhibiting and hyperglycemic hormone in the eyestalk of hrachyuran crustaceans. Cell Tissue Res. 1988; 251: 3–12
  • Mangerich S, Keller R, Dircksen H, Rao RK, Riehm JP. Immunocytochemical localization of pigment-dispersing hormone (PDH) and its coexistence with FMRF-amide immunoreactive material in the eyestalks of the decapod crustaceans Carcinus muenas and Orconectes limosus. Cell Tissue Res 1986; 245: 377–86
  • Aréchiga H, Chavez B, Glantz RM. Dye-coupling and gap-junctions between crustacean neurosecretory cells. Brain Res 1985; 326: 183–7
  • Aréchiga H, Flores López J, García U. Control of biosynthesis and release of the crustacean neurode-pressing hormone. Current trends in comparative endocrinology, B Lofts, WM Holms. University Press, Hong Kong 1985; 787–91
  • Glantz RM, Kirk MD, Aréchiga H. Light input to crustacean neurosecretory cells. Brain Res 1983; 265: 307–11
  • Nagano M, Cooke IM. Comparison of electrical responses of terminals, axons and somata of a pepti-dergic neurosecretory system. J Neurosci 1988; 7: 634–8
  • Onetti C, García U, Valdiosera RF, Aréchiga H. Ionic currents in crustacean neurosecretory cells. J Neurophysiol 1990; 64: 1514–26
  • Arechiga Cabrera- H, Peralta C, Huberman A. Functional characterization of the neuro-depressing hormone in the crayfish. J Neurobiol 1979; 10: 409–22
  • Page TL, Larimer J. Neural control of circadian rhythmicity in the crayfish. I. The locomotor rhythm. J Comp Physiol 1975; 97: 59–80
  • Page T, Larimer LJ. Neural control of circadian rhythmicity in the crayfish. II. The ERG amplitude rhythm. J Comp Physiol 1975; 97: 81–96
  • Barrera-Mera B. Effect of cerebroid ganglion lesions on ERG circadian rhythm in the crayfish. Physiol Behav 1976; 17: 59–64
  • Larimer JL, Smith JT. Circadian rhythm of retinal sensitivity in crayfish: modulation by the cerebral and optic ganglia. J Camp Physiol 1980; 136: 313–26
  • Barrera-Mera B. Neural coupling between left and right electroretinographic circadian oscillations in the crayfish P Bouvieri. Comp Biochem Physiol 1978; 61A: 427–32
  • Aréchiga H. Circadian rhythmicity in the nervous system of crustaceans. Fed Proc 1977; 36: 2036–41
  • Wine JJ, Mittenthal J, Kennedy DM. The structure of tonic flexor motoneurons in crayfish abdominal ganglia. J Comp Physiol 1974; 93: 315–35
  • Edwards DH. Crayfish extraretinal photoreception. I. Behavioural and motoneuron responses to abdominal illumination. J Exp Biol 1984; 109: 291–306
  • Page TL, Larimer J. Extraretinal photoreception in entrainment of crustacean circadian rhythms. Photochem Photobiol 1976; 23: 245–51
  • Fuentes-Pardo B, Inclán-Rubio V. Caudal pholoreceptors synchronize circadian rhythms in crayfish. I. Synchronization of ERG and locomotor circadian rhythm. Comp Biochem Physiol 1987; 86A: 523–7
  • Aréchiga H, Atkinson R JA. The eye and some effect of light on the locomotor activity in Nephrops norvegicus. Marine Biol 1975; 32: 63–76
  • Glantz RM. Peripheral versus central adaptation in the crustacean visual system. J Neurophysiol 1971; 34: 485–92
  • Simon TW, Edwards DH. Light-evoked walking in the crayfish: behavioral and neuronal responses triggered by the caudal photoreceptor. J Comp Physiol [A] 1990; 166: 745–55
  • Aréchiga H. Circadian modulation of behavior in crustaceans. Neurosci Res Prog Bull 1979; 17: 672–9
  • Kravitz EA. Hormonal control of behavior: amines as gain-setting elements that bias behavioral output in lobsters. Amer Zool 1990; 30: 595–608
  • Fernández de Miguel F, Cohen J, Zamora L, Aréchiga H. An automated system for detection and analysis of locomotor behavior in crustaceans. Bol Eslud Med Biol Mex 1989; 37: 71–6
  • Rao KR. Pigmentary effectors. The biology of Crustacea, DE Bliss, LH Mantel. Academic Press, New York 1985; vol. 9.: 362–95
  • Thurman C. Rhythmic physiological color change in Crustacea: a review. Comp Biochem Physiol 1988; 91C: 171–85
  • Beltz SB. Crustacean neurohormones. Invertebrate endocrinology (endocrinology of selected invertebrate types), H Laufer, R GH Downer. Alan R. Liss, New York 1988; vol. 2: 235–58

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