John Woodland Hastings | Academic Influence

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John Woodland Hastings

Biology

#1506

World Rank

#2506

Historical Rank

#745

USA Rank

Marine Biology

#8

World Rank

#10

Historical Rank

#4

USA Rank

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Biology

John Woodland Hastings's Degrees

PhD Biology University of California, Berkeley
Bachelors Biology University of California, Berkeley

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Why Is John Woodland Hastings Influential?

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According to Wikipedia, John Woodland "Woody" Hastings, was a leader in the field of photobiology, especially bioluminescence, and was one of the founders of the field of circadian biology . He was the Paul C. Mangelsdorf Professor of Natural Sciences and Professor of Molecular and Cellular Biology at Harvard University. He published over 400 papers and co-edited three books.

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John Woodland Hastings's Published Works

Number of citations in a given year to any of this author's works

Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author

Published Works

Cellular Control of the Synthesis and Activity of the Bacterial Luminescent System (1970) (1174)
Bacterial bioluminescence: its control and ecological significance. (1979) (685)
BIOLUMINESCENCE AND CHEMILUMINESCENCE (1976) (478)
Total Quantum Flux of Isotropic Sources (1963) (373)
Energy transfer in a bioluminescent system (1971) (372)
Chemistries and colors of bioluminescent reactions: a review. (1996) (314)
Membrane model for the circadian clock (1974) (279)
Induction of luciferase synthesis in Beneckea harveyi by other marine bacteria (1979) (277)
ON THE MECHANISM OF TEMPERATURE INDEPENDENCE IN A BIOLOGICAL CLOCK. (1957) (271)
A nuclear-encoded form II RuBisCO in dinoflagellates. (1995) (261)
A PERSISTENT DIURNAL RHYTHM OF LUMINESCENCE IN GONYAULAX POLYEDRA (1958) (248)
Rhythmic Cell Division in Populations of Gonyaulax polyedra (1958) (227)
Biochemistry and physiology of bioluminescent bacteria. (1985) (206)
Biological diversity, chemical mechanisms, and the evolutionary origins of bioluminescent systems (2005) (196)
Circadian regulation of bioluminescence in Gonyaulax involves translational control. (1989) (176)
Bacterial bioluminescence. (1977) (176)
A stable, inexpensive, solid-state photomultiplier photometer. (1971) (164)
Purification and properties of bacterial luciferases. (1972) (157)
Quorum Sensing: the Explanation of a Curious Phenomenon Reveals a Common Characteristic of Bacteria (1999) (149)
The oxidation of reduced flavin mononucleotide by molecular oxygen. (1962) (147)
Characteristics of the diurnal rhythm of luminescence in gonyaulax polyedra (1957) (146)
Spectral properties of an oxygenated luciferase-flavin intermediate isolated by low-temperature chromatography. (1973) (145)
Biochemistry of the bioluminescence of colonial hydroids and other coelenterates (1971) (137)
A Persistent Daily Rhythm in Photosynthesis (1961) (135)
[14] Bacterial luciferase: Assay, purification, and properties (1978) (134)
Response of Aequorin Bioluminescence to Rapid Changes in Calcium Concentration (1969) (129)
ACTIVATION OF BACTERIAL ENDOSPORES (1964) (119)
THE PURIFICATION PROPERTIES, AND CHEMILUMINESCENT QUANTUM YIELD OF BACTERIAL LUCIFERASE. (1965) (119)
Structurally distinct bacterial luciferases. (1969) (119)
Planktonic Marine Luminous Bacteria: Species Distribution in the Water Column (1980) (117)
Circadian expression of the luciferin-binding protein correlates with the binding of a protein to the 3' untranslated region of its mRNA. (1994) (112)
Different Regulatory Mechanisms Modulate the Expression of a Dinoflagellate Iron-Superoxide Dismutase* (2001) (112)
Effects of temperature upon diurnal rhythms. (1960) (110)
Mutationally altered bacterial luciferase. Implications for subunit functions. (1972) (110)
NOVEL DINOFLAGELLATE CLOCK‐RELATED GENES IDENTIFIED THROUGH MICROARRAY ANALYSIS 1 (2003) (110)
Structure of dinoflagellate luciferin and its enzymic and nonenzymic air-oxidation products (1989) (110)
Molecular cloning and genomic organization of a gene for luciferin-binding protein from the dinoflagellate Gonyaulax polyedra. (1993) (107)
Voltage-gated proton channel in a dinoflagellate (2011) (105)
Bioluminescence: mechanism and mode of control of scintillon activity. (1972) (105)
Light for All Reasons: Versatility in the Behavioral Repertoire of the Flashlight Fish (1975) (103)
Action Spectrum for Resetting the Circadian Phototaxis Rhythm in the CW15 Strain of Chlamydomonas: I. Cells in Darkness. (1991) (99)
Structure and organization of the peridinin-chlorophyll a-binding protein gene in Gonyaulax polyedra (1997) (96)
A substrate-binding protein in the Gonyaulax bioluminescence reaction. (1971) (96)
Light to Hide by: Ventral Luminescence to Camouflage the Silhouette (1971) (93)
Bacterial luciferase. Binding of oxidized flavin mononucleotide. (1975) (91)
The oxygenated bacterial luciferase-flavin intermediate. Reaction products via the light and dark pathways. (1975) (90)
Binding site determination from kinetic data. Reduced flavin mononucleotide binding to bacterial luciferase. (1971) (89)
The Action Spectrum for Shifting the Phase of the Rhythm of Luminescence in Gonyaulax polyedra (1960) (88)
The Biological Clock: Two Views (1970) (87)
Circadian Changes in Enzyme Concentration Account for Rhythm of Enzyme Activity in Gonyaulax (1984) (85)
Action Spectra for Two Effects of Light on Luminescence in Gonyaulax polyedra (1959) (83)
Characterization of the bioluminescent organelles in Gonyaulax polyedra (dinoflagellates) after fast-freeze fixation and antiluciferase immunogold staining (1987) (83)
Circadian Oscillation of Nitrate Reductase Activity in Gonyaulax polyedra Is Due to Changes in Cellular Protein Levels (1995) (82)
Bacterial luciferase. Chemistry of the reactive sulfhydryl. (1974) (79)
What is the clock? Translational regulation of circadian bioluminescence. (1990) (79)
Circadian synthesis of a nuclear-encoded chloroplast glyceraldehyde-3-phosphate dehydrogenase in the dinoflagellate Gonyaulax polyedra is translationally controlled. (1999) (79)
Evidence for tetradecanal as the natural aldehyde in bacterial bioluminescence. (1979) (78)
The circadian bioluminescence rhythm of Gonyaulax is related to daily variations in the number of light-emitting organelles. (1990) (78)
Genome-wide analysis of redox-regulated genes in a dinoflagellate. (2003) (77)
Fluorescence and bioluminescence of bacterial luciferase intermediates. (1975) (76)
Evidence for similar biochemical requirements for bioluminescence among the coelenterates (1973) (74)
A postulated mechanism for the bioluminescent oxidation of reduced flavin mononucleotide. (1972) (72)
The Effects of Inhibitors of Macromolecular Biosynthesis upon the Persistent Rhythm of Luminescence in Gonyaulax (1963) (72)
The luminescent reaction in extracts of the marine dinoflagellate, Gonyaulax polyedra. (1957) (70)
The effect of flavin isomers and analogues upon the color of bacterial bioluminescence. (1969) (69)
No Desynchronization among Four Circadian Rhythms in the Unicellular Alga, Gonyaulax polyedra (1972) (69)
The biological clock in Gonyaulax controls luciferase activity by regulating turnover. (1981) (69)
Inhibitors of protein synthesis on 80S ribosomes phase shift the Gonyaulax clock. (1982) (67)
Catabolite repression of bacterial bioluminescence: functional implications. (1972) (66)
Dinoflagellate bioluminescence: A comparative study of invitro components (1976) (66)
A Circadian Rhythm of Population Behavior in Gonyaulax polyedra (1989) (66)
Different Phase Responses of the Two Circadian Oscillators in Gonyaulax (1994) (65)
Myristic acid stimulation of bacterial bioluminescence in "aldehyde" mutants. (1978) (65)
Growth and luminescence of the bacterium Xenorhabdus luminescens from a human wound (1989) (65)
Compartmentalization of algal bioluminescence: autofluorescence of bioluminescent particles in the dinoflagellate Gonyaulax as studied with image-intensified video microscopy and flow cytometry (1985) (64)
THE INFLUENCE OF ALDEHYDE CHAIN LENGTH UPON THE RELATIVE QUANTUM YIELD OF THE BIOLUMINESCENT REACTION OF ACHROMOBACTER FISCHERI. (1963) (63)
Characterization and postulated structure of the primary emitter in the bacterial luciferase reaction. (1984) (62)
Quorum Sensing on a Global Scale: Massive Numbers of Bioluminescent Bacteria Make Milky Seas (2006) (61)
ENDOSYMBIOTIC BIOLUMINESCENT BACTERIA FROM THE LIGHT ORGAN OF PONY FISH (1971) (58)
Three functional luciferase domains in a single polypeptide chain. (1997) (58)
Luminescent "Crystalline" Particles: An Organized Subcellular Bioluminescent System (1963) (58)
Role of a luciferin-binding protein in the circadian bioluminescent reaction of Gonyaulax polyedra. (1989) (57)
Circadian Phototransduction: Phase Resetting and Frequency of the Circadian Clock of Gonyaulax Cells in Red Light1 (1989) (57)
The mechanism of action of pyrophosphate in firefly luminescence. (1953) (57)
Intermediates in the bioluminescent oxidation of reduced flavin mononucleotide. (1963) (57)
Mechanism of bacterial bioluminescence: 4a,5-dihydroflavin analogs as models for luciferase hydroperoxide intermediates and the effect of substituents at the 8-position of flavin on luciferase kinetics. (1993) (56)
The requirement of riboflavin phosphate for bacterial luminescence. (1953) (55)
The Gonyaulax clock at 50: translational control of circadian expression. (2007) (54)
Bioluminescence: Living Lights, Lights for Living (2013) (54)
An Inhibitor of Protein Phosphorylation Stops the Circadian Oscillator and Blocks Light-Induced Phase Shifting in Gonyaulax polyedra (1994) (54)
THE CIRCADIAN RHYTHM OF BIOLUMINESCENCE IN PYROCYSTIS IS NOT DUE TO DIFFERENCES IN THE AMOUNT OF LUCIFERASE: A COMPARATIVE STUDY OF THREE BIOLUMINESCENT MARINE DINOFLAGELLATES (1998) (53)
Bacterial bioluminescence: its control and ecological significance (1979) (53)
Members of a dinoflagellate luciferase gene family differ in synonymous substitution rates. (2001) (52)
On the physical identity of scintillons: bioluminescent particles in Gonyaulax polyedra. (1972) (52)
Oxygen concentration and bioluminescence intensity. I. Bacteria and fungi. (1952) (52)
Action Spectrum for Resetting the Circadian Phototaxis Rhythm in the CW15 Strain of Chlamydomonas: II. Illuminated Cells. (1991) (52)
Biochemical aspects of rhythms: phase shifting by chemicals. (1960) (52)
Crystal structure of a pH-regulated luciferase catalyzing the bioluminescent oxidation of an open tetrapyrrole. (2005) (50)
The effect of oxygen upon the immobilization reaction in firefly luminescence. (1953) (50)
Activity and stability of the luciferase--flavin intermediate. (1978) (49)
Purification of the yellow fluorescent protein from Vibrio fischeri and identity of the flavin chromophore. (1987) (48)
Acute and chronic effects of toxic metals on viability, encystment and bioluminescence in the dinoflagellate Gonyaulax polyedra. (1999) (48)
A circadian rhythm in the activity of superoxide dismutase in the photosynthetic alga Gonyaulax polyedra. (1992) (47)
Functional differences of the nonidentical subunits of bacterial luciferase. Properties of hybrids of native and chemically modified bacterial luciferase. (1971) (47)
Acquisition of Circadian Bioluminescence Data in Gonyaulax and an Effect of the Measurement Procedure on the Period of the Rhythm (1986) (47)
Inhibitors of Serine/Threonine Phosphoprotein Phosphatases Alter Circadian Properties in Gonyaulax polyedra (1996) (47)
Cell growth kinetics, division asymmetry and volume control at division in the marine dinoflagellate Gonyaulax polyedra: a model of circadian clock control of the cell cycle. (1989) (46)
BIOCHEMISTRY OF RHYTHMIC SYSTEMS * (1962) (46)
CIRCADIAN REGULATION OF BIOLUMINESCENCE IN THE DINOFLAGELLATE PYROCYSTIS LUNULA 1 (1993) (46)
A time-dependent bacterial bioluminescence emission spectrum in an in vitro single turnover system: energy transfer alone cannot account for the yellow emission of Vibrio fischeri Y-1. (1990) (45)
The s phase is discrete and is controlled by the circadian clock in the marine dinoflagellate Gonyaulax polyedra. (1989) (45)
The mRNA level of the circadian regulated Gonyaulax luciferase remains constant over the cycle. (1998) (45)
Structure of the oxygen adduct intermediate in the bacterial luciferase reaction: C nuclear magnetic resonance determination. (1978) (45)
[13] Bacterial bioluminescence: An overview (1978) (44)
The Characterization of Scintillons (1968) (43)
A sensitive assay for proteolytic enzymes using bacterial luciferase as a substrate. (1974) (43)
Molecular evolution of dinoflagellate luciferases, enzymes with three catalytic domains in a single polypeptide. (2004) (43)
Bacterial luciferase. The hydrophobic environment of the reactive sulfhydryl. (1974) (42)
Creatine accelerates the circadian clock in a unicellular alga (1988) (42)
Hybridization of bacterial luciferase with a variant produced by chemical modification. (1971) (42)
THE PURIFICATION AND PROPERTIES OF THE BIOLUMINESCENT SYSTEM IN GONYAULAX POLYEDRA. (1963) (41)
Daily Rhythm of Luciferin Activity in Gonyaulax polyedra (1963) (41)
Mutated luciferases with altered bioluminescence emission spectra. (1974) (40)
Conditionality of circadian rhythmicity: Synergistic action of light and temperature (2004) (40)
Glutamate Functions in Osmoregulation in a Marine Bacterium (1979) (40)
Nonidentical subunits of bacterial luciferase: their isolation and recombination to form active enzyme. (1967) (39)
Two photoreceptors control the circadian clock of a unicellular alga (1988) (39)
How are growth and luminescence regulated independently in light organ symbionts (1987) (39)
ARE THE EFFECTS OF LIGHT ON PHASE AND PERIOD OF THE Gonyaulax CLOCK MEDIATED BY DIFFERENT PATHWAYS? (1991) (39)
Bacterial luciferase requires one reduced flavin for light emission. (1975) (38)
The effects of protein synthesis inhibitors on theGonyaulax clock: II. The effect of cycloheximide on ultrastructural parameters (1980) (38)
Heavy water slows the Gonyaulax clock: a test of the hypothesis that D2O affects circadian oscillations by diminishing the apparent temperature. (1974) (38)
The reversibility of the denaturation of bacterial luciferase. (1967) (38)
The molecular basis of circadian rhythms : report of the Dahlem Workshop on the Molecular Basis of Circadian Rhythms, Berlin 1975, November 3 to 7 (1976) (37)
Biochemistry of dinoflagellate bioluminescence: purification and characterization of dinoflagellate luciferin from Pyrocystis lunula. (1981) (37)
Calcium-triggered light emission in Renilla. A unitary biochemical scheme for coelenterate bioluminescence. (1969) (37)
Cloning, sequencing and expression of dinoflagellate luciferase DNA from a marine alga, Gonyaulax polyedra. (1994) (36)
Two different domains of the luciferase gene in the heterotrophic dinoflagellate Noctiluca scintillans occur as two separate genes in photosynthetic species (2007) (36)
Bioluminescence: pH Activity Profies of Related Luciferase Fractions (1968) (35)
Kinetic studies on the mechanism of bacterial NAD(P)H:flavin oxidoreductase. (1979) (35)
The specificity of symbiosis: Pony fish and luminescent bacteria (1977) (35)
Differential effects of 8-anilino-1-naphthalenesulfonate upon binding of oxidized and reduced flavines by bacterial luciferase. (1975) (35)
Circadian rhythms: mechanism of luciferase activity changes in Gonyaulax. (1972) (34)
The role of oxygen in the photoexcited luminescence of bacterial luciferase. (1967) (34)
Chemical and biological aspects of singlet excited molecular oxygen. (1970) (34)
Circadian rhythm data collection with the apple II microcomputer (1982) (33)
Mutants of luminous bacteria with an altered control of luciferase synthesis (1977) (33)
Low oxygen is optimal for luciferase synthesis in some bacteria (1977) (33)
Self-Protection against Cell Wall Hydrolysis inStreptococcus milleri NMSCC 061 and Analysis of the Millericin B Operon (2001) (32)
PARTIAL PURIFICATION AND PROPERTIES OF BACTERIAL LUCIFERIN AND LUCIFERASE (1954) (32)
COMPARATIVE STUDY OF LUMINESCENT AND NONLUMINESCENT STRAINS OF GONYAULAX EXCAVATA (PYRRHOPHYTA) 1, 2 (1978) (31)
Spectral detection of an intermediate preceding the excited state in the bacterial luciferase reaction. (1993) (31)
The ultrastructural localization of luciferase in three bioluminescent dinoflagellates, two species of Pyrocystis, and Noctiluca, using anti-luciferase and immunogold labelling. (1987) (31)
Marine Transducing Bacteriophage Attacking a Luminous Bacterium (1974) (30)
Isolation and characterization of the transient, luciferase-bound flavin-4a-hydroxide in the bacterial luciferase reaction (1987) (30)
CLONING, EXPRESSION, AND CHARACTERIZATION OF A HISTONE‐LIKE PROTEIN FROM THE MARINE DINOFLAGELLATE LINGULODINIUM POLYEDRUM (DINOPHYCEAE)1 (2002) (30)
Dinoflagellate luciferin is structurally related to chlorophyll (1981) (30)
Circadian Rhythm of Photoaccumulation in Paramecium bursaria (1989) (30)
Oxygen Affinities of the Bioluminescence Systems of Various Species of Luminous Bacteria (1985) (29)
Chapter 11 – THE ROLE OF LIGHT IN PERSISTENT DAILY RHYTHMS1 (1964) (29)
ON THE MOLECULAR MECHANISM OF BIOLUMINESCENCE. I. THE ROLE OF LONG-CHAIN ALDEHYDE. (1964) (29)
The inhibition of bacterial luciferase by mixed function oxidase inhibitors. (1972) (28)
Control of aldehyde synthesis in the luminous bacterium Beneckea harveyi (1979) (28)
Circadian control over synthesis of manyGonyaulax proteins is at a translational level (1990) (27)
Novel Effects on the Gonyaulax Circadian System Produced by the Protein Kinase Inhibitor Staurosporine (1999) (27)
Are Protein Synthesis Inhibition and Phase Shifting of the Circadian Clock in Gonyaulax Correlated? (1987) (27)
Two Bioluminescent Diptera: The North American Orfelia fultoni and the Australian Arachnocampa flava. Similar Niche, Different Bioluminescence Systems ¶ (2002) (27)
Bacterial quorum-sensing signals are inactivated by mammalian cells (2004) (27)
[28] Cell-free components in dinoflagellate bioluminescence. The particulate activity: Scintillons; the soluble components: Luciferase, luciferin, and luciferin-binding protein (1986) (26)
Structure of Dinoflagellate Luciferin and Its Enzymatic and Nonenzymatic Air-Oxidation Products (1990) (26)
Flavin mononucleotide reductase of luminous bacteria (1975) (26)
Bioluminescence emission from the reaction of luciferase-flavin mononucleotide radical with O2-.. (1983) (26)
Proteolytic inactivation of the luciferase from the luminous marine bacterium Beneckea harveyi. (1978) (25)
An active proteolytic fragment of Gonyaulax luciferase. (1974) (25)
N-terminal intramolecularly conserved histidines of three domains in Gonyaulax luciferase are responsible for loss of activity in the alkaline region. (2001) (24)
Crossreactivity between the light-emitting systems of distantly related organisms: Novel type of light-emitting compound. (1980) (24)
Two Bioluminescent Diptera: The North American Orfelia fultoni and the Australian Arachnocampa flava. Similar Niche, Different Bioluminescence Systems¶ (2002) (24)
Membrane polypeptides co-induced with the bacterial bioluminescent system. (1977) (24)
Temperature-sensitive mutants of bioluminescent bacteria. (1971) (23)
Critical pulses of anisomycin drive the circadian oscillator inGonyaulax towards its singularity (1982) (23)
Bioluminescence and chemiluminescence : molecular reporting with photons : proceedings of the 9th International Symposium on Bioluminescence and Chemiluminescence at Woods Hole, Massachusetts, October 1996 (1997) (23)
Immunogold labeling of organelles in the bioluminescent dinoflagellate Gonyaulax polyedra with anti-luciferase antibody. (1985) (23)
Cell Cycle Synchronization of Gonyaulax polyedra by Filtration: Quantized Generation Times (1988) (23)
Membranes and molecules in circadian systems. (1976) (23)
COUNTING AND SIZING OF UNICELLULAR MARINE ORGANISMS * (1962) (22)
NOVEL AND RAPIDLY DIVERGING INTERGENIC SEQUENCES BETWEEN TANDEM REPEATS OF THE LUCIFERASE GENES IN SEVEN DINOFLAGELLATE SPECIES 1 (2006) (22)
Physical interaction and activity coupling between two enzymes induced by immobilization of one. (1980) (22)
A LOW INTENSITY PERMANENT LIQUID LIGHT STANDARD ACTIVATED BY RADIOACTIVITY (1965) (22)
Bioluminescence in Bacteria and Dinoflagellates (1986) (22)
INHIBITION OF THE BIOLUMINESCENT OXIDATION OF REDUCED FLAVIN MONONUCLEOTIDE BY 2-DECENAL. (1963) (22)
THE LUMINESCENCE OF THE MILLIPEDE, LUMINODESMUS SEQUOIAE (1957) (22)
Molecular Mechanisms in Bacterial Bioluminescence: On Energy Storage Intermediates and the Role of Aldehyde in the Reaction (1967) (21)
The inhibition of a biological clock by actinomycin D. (1962) (21)
A BLUE FLUORESCENT PROTEIN FROM A YELLOW‐EMITTING LUMINOUS BACTERIUM (1992) (21)
Structure and catalytic inactivity of the bacterial luciferase neutral flavin radical. (1982) (21)
The effects of protein synthesis inhibitors on theGonyaulax clock (1980) (21)
THE FIREFLY PSEUDOFLASH IN RELATION TO PHOTOGENIC CONTROL (1956) (21)
Circadian spontaneous bioluminescent glow and flashing ofGonyaulax polyedra (1980) (20)
Bacterial Bioluminescence In Vivo: Control and Synthesis of Aldehyde Factor in Temperature-Conditional Luminescence Mutants (1974) (20)
Two active forms of the accessory yellow fluorescence protein of the luminous bacterium Vibrio fischeri strain Y1 (1993) (20)
A sensitive and specific assay for superoxide anion released by neutrophils or macrophages based on bioluminescence of polynoidin. (1990) (20)
Reversible steps in the reaction of aldehydes with bacterial luciferase intermediates. (1979) (19)
Chemistry and control of luminescence in marine organisms (1983) (19)
BIOLUMINESCENCE FROM THE REACTION OF FMN, H2O2 AND LONG CHAIN ALDEHYDE WITH BACTERIAL LUCIFERASE (1979) (19)
Structural studies on bacterial luciferase using energy transfer and emission anisotropy. (1978) (19)
Bioluminescence and chemiluminescence. (2003) (19)
SYMPOSIUM‐IN‐PRINT (1995) (18)
Structural variations in nisin associated with different membrane mimicking and pH environments. (1998) (18)
Luciferase‐dependent growth of cytochrome‐deficient Vibrio harveyi (1986) (18)
Differential translational initiation of lbp mRNA is caused by a 5′ upstream open reading frame 1 (1997) (17)
Characterization of Non-O1 Serovar Vibrio cholerae (Vibrio albensis) (1985) (17)
The effects of protein synthesis inhibitors on theGonyaulax clock (1980) (17)
Iron represses bioluminescence and affects catabolite repression of luminescence inVibrio harveyi (1982) (16)
Precision of the Gonyaulax circadian clock. (1981) (16)
Bacterial luciferase activity does not require a disulfide-dithiol conversion. (1977) (16)
STEPS IN THE POPULATION OF THE EMITTER IN THE BACTERIAL LUCIFERASE REACTION (1979) (16)
Poising of the arginine pool and control of bioluminescence in Beneckea harveyi (1979) (16)
Effects of aldehyde and internal ions on bioluminescence expression of Photobacterium phosphoreum (1991) (16)
Growth, luminescence, respiration, and the ATP pool during autoinduction in Beneckea harveyi (1978) (16)
Induction of bacterial luciferase by pure oxygen (1992) (16)
Scintillons: The Biochemistry of Dinoflagellate Bioluminescence (1967) (15)
Chemistry, clones, and circadian control of the dinoflagellate bioluminescent system. The Marlene DeLuca memorial lecture. (1989) (15)
Exploring the signaling pathway of circadian bioluminescence (1996) (15)
Oxygen dependent and independent steps in luciferase-FMNH2 oxidation. (1978) (14)
A transcriptional and proteomic survey of Arachnocampa luminosa (Diptera: Keroplatidae) lanterns gives insights into the origin of bioluminescence from the Malpighian tubules in Diptera. (2015) (14)
Activity and subunit functions of immobilized bacterial luciferase. (1982) (14)
Modification of a synthetic antimicrobial peptide (ESF1) for improved inhibitory activity. (1998) (14)
Biogenesis of sulfonium compounds in a dinoflagellate; methionine cascade (1997) (14)
Fifty Years of Fun (2001) (13)
Specificities and properties of three reduced pyridine nucleotide-flavin mononucleotide reductases coupling to bacterial luciferase (1982) (13)
Inhibition of bacterial bioluminescence by pargyline. (1979) (13)
Subunit homologies in bacterial luciferases. (1970) (13)
ON THE MOLECULAR MECHANISM OF BIOLUMINESCENCE, II. LIGHT-INDUCED LUMINESCENCE. (1965) (13)
Temperature Dependence of Phase Response Curves for Drug-Induced Phase Shifts (1989) (13)
A Type-1 Phosphoprotein Phosphatase from a Dinoflagellate as a Possible Component of the Circadian Mechanism (2003) (12)
Cellular and Molecular Mechanisms of Circadian Regulation in the Unicellular Dinoflagellate Gonyaulax polyedra (2001) (12)
Circadian Rhythms in Dinoflagellates: What Is the Purpose of Synthesis and Destruction of Proteins? (2013) (12)
Subunit exchange between and specific activities of mutant bacterial luciferases. (1980) (12)
Oxygen concentration and bioluminescence intensity. II. Cypridina hilgendorfii. (1952) (12)
Expression of luminescence in Photobacterium phosphoreum: Na+ regulation of in vivo luminescence appearance (1986) (12)
[Book Review: Aglow in the Dark: The Revolutionary Science of Biofluorescence] (2006) (11)
[20] Bioassay for myristic acid and long-chain aldehydes (1978) (11)
Bacterial luciferase subunits are synthesized in equal quantities. (1977) (11)
Phase and Period Effects of Physical and Chemical Factors. Do Cells Communicate (1985) (11)
Factors affecting the cellular expression of bacterial luciferase (1981) (11)
Bacterial bioluminescence light emission in the mixed function oxidation of reduced flavin and fatty aldehyde. (1978) (11)
Protein synthesis and protein turnover in circadian cycles. (1981) (11)
Photons for reporting molecular events: green fluorescent protein and four luciferase systems. (2005) (11)
Enhancement of light emission in the bacterial luciferase reaction by H2O2. (1987) (11)
Flavin binding by bacterial luciferase: affinity chromatography of bacterial luciferase. (1974) (11)
Expression of the cloned subunits of bacterial luciferase from separate replicons. (1985) (10)
Temporal Regulation in the Individual Gonyaulax Cell (1981) (10)
BORONIC ACIDS AS MECHANISTIC PROBES FOR THE BACTERIAL LUCIFERASE REACTION (1991) (10)
AUTOINDUCTION AND ALDEHYDE CHAIN‐LENGTH EFFECTS ON THE BIOLUMINESCENT EMISSION FROM THE YELLOW PROTEIN ASSOCIATED WITH LUCIFERASE IN Vibrio fischeri STRAIN Y‐1b (1989) (10)
Bioluminescence: from chemical bonds to photons. (1975) (10)
A bacterial luciferase reaction with a negative temperature coefficient attributable to protein-protein interaction. (1995) (10)
Bovine serum albumin interacts with bacterial luciferase. (1991) (10)
Gonyauline: A novel endogenous substance shortening the period of the circadian clock of a unicellular alga (1991) (10)
The Chemistry of Bioluminescence (1966) (9)
CELLULAR-BIOCHEMICAL CLOCK HYPOTHESIS (1970) (9)
[54] Bacterial luciferase: FMNH2-aldehyde oxidase (1978) (9)
Inhibition and stimulation of the development of the bioluminescent system in Beneckea harveyi by cyclic GMP. (1976) (9)
THE CHEMISTRY AND BIOLOGY OF BACTERIAL LIGHT EMISSION (1978) (8)
Inhibition of bioluminescence in Photobacterium phosphoreum by sulfamethizole and its stimulation by thymine. (1990) (8)
Circadian communication between unicells? (1986) (8)
[12] Bacterial luciferase intermediates: The neutral flavin semiquinone, its reaction with superoxide, and the flavin 4a-hydroxide (1986) (8)
Luciferases and Light-emitting Accessory Proteins: Structural Biology (2014) (7)
Cationic peptides with antimicrobial activity : The new generation of antibiotics ? (1999) (7)
The absence of a correlation between plasmids and luminescence in marine luminous bacteria (1982) (7)
Stabilization of luciferase intermediates by fatty amines, amides, and nitriles. (1992) (7)
Precision of theGonyaulax circadian clock (1981) (7)
Bacterial Bioluminescence. Mechanistic Implications of Active Center Chemistry of Luciferase (1973) (7)
EVIDENCE FOR HIGH ENERGY STORAGE INTERMEDIATES IN BIOLUMINESCENCE (1965) (7)
Minute-long pulses of anisomycin phase-shift the biological clock in Gonyaulax by hours (1982) (6)
Expression of bacterial luminescence is stimulated by nalidixic acid in a nalidixic acid resistant mutant (1990) (5)
Solubilization of molecular elements of scintillons: Bioluminescent particles from dinoflagellates (1974) (5)
[21] The luciferase reduced flavin hydroperoxide intermediate (1978) (5)
The biology of circadian rhythms from man to micro-organism. (1970) (5)
IN SITU HYBRIDIZATION OF LUCIFERIN‐BINDING PROTEIN ANTI‐SENSE RNA TO THIN SECTIONS OF THE BIOLUMINESCENT DINOFLAGELLATE GONYAULAX POLYEDRA 1 (1991) (5)
Period shortening and phase shifting effects of ethanol on theGonyaulax glow rhythm (1979) (5)
The Preparation and Standardization by Different Methods of Liquid Light Sources (1967) (5)
The properties of mnemiopsin, a bioluminescent and light sensitive protein purified by hollow fiber techniques (1978) (5)
Formation of hybrid luciferases from subunits of different species of Photobacterium. (1980) (5)
Phase Determination of the Circadian Rhythm of Conidiation in Heterocaryons between two out-of-Phase Mycelia in Neurospora crassa (1989) (5)
Cellular autonomy of the Gonyaulax circadian clock. (1982) (5)
BIOLUMINESCENCE OF BACTERIAL LUCIFERASE * (1981) (5)
Fluorescence Properties of Luciferase Peroxyflavins Prepared with ISO-FMN and 2-THIO FMN (1981) (5)
Chapter 52 – Bioluminescence (2012) (4)
A circadian rhythm of the luciferin binding protein fromGonyaulax polyedra (1978) (4)
Bacterial luciferase: FMNH2-aldehyde oxidase. (1978) (4)
Expression and localization of bacterial luciferase determined by immunogold labeling (1989) (4)
Firefly flashes and royal flushes: life in a full house. (1989) (4)
Bioluminescence emission of bacterial luciferase with 1-deaza-FMN. Evidence for the noninvolvement of N(1)-protonated flavin species as emitters. (1989) (4)
Quantitative determinations of aminotransferases and dehydrogenases by means of the Bacterial Luciferase System (1982) (4)
Light-induced bioluminescence. Isolation and characterization of a specific protein involved in the absorption and delayed emission of light. (1970) (4)
Glutamate Functions inOsmoregulation inaMarine Bacterium (1979) (4)
Rhythms in Dinoflagellates (1973) (3)
Biochemistry and Circadian Regulation of Output from the Gonyaulax Clock : Are There Many Clocks or Simply Many Hands ? (3)
Chapter 3:Progress and Perspectives on Bioluminescence: from Luminous Organisms to Molecular Mechanisms (2010) (3)
Aldehydes phase shift theGonyaulax clock (1979) (3)
Photosomes and Scintillons (1987) (3)
THE USE OF THE BACTERIAL LUMINESCENT SYSTEM FOR THE QUANTITATIVE DETERMINATION OF DEHYDROGENASES (1981) (3)
Bacterial luciferase : bioluminescence emission using lumanzines as substrates (1994) (3)
Characterization and crystallization of active domains of a novel luciferase from a marine dinoflagellate. (2003) (3)
Photoexcited bacterial luminescence. Spectral properties and mechanistic implication of a reduced flavine-like prosthetic group associated with photoexcitable luciferase. (1975) (3)
Autoinduction in a luminous bacterium: A confirmation of the hypothesis (1979) (3)
Phase of the circadian clock is accurately transferred from mother to daughter cells in the dinoflagellateGonyaulax polyedra (2008) (3)
Changes in the ultrastructural localization of mRNA for a circadian regulated protein. (1996) (3)
Cellular autonomy of theGonyaulax circadian clock (1982) (2)
CLONING, SEQUENCING AND EXPRESSION OF A HISTONE‐LIKE PROTEIN FROM THE PHOTOSYNTHETIC DINOFLAGELLATE GONYAULAX POLYEDRA (2000) (2)
Effectiveness of the Accessory Yellow Fluorescent Protein in the Bacterial Luciferase Reaction Correlates with the Lifetime of the Peroxyhemiacetal Intermediate: The Stereochemistry of the Reaction (1997) (2)
Identification of the luciferase-bound flavin-4a-hydroxide as the primary emitter in the bacterial bioluminescence reaction (1984) (2)
Studies on the bacterial luciferase reaction : Isotope effects on the light emission (1984) (2)
The Bacterial Luciferase Neutral Flavin Radical : Identification and Catalytic Inactivity (1982) (2)
Superoxide anion reacts with enzyme intermediate in the bacterial luciferase reaction competitive with intramolecular electron transfer. (1997) (2)
Day-night differences are not always due to circadian control. (1992) (2)
Reversible inhibition of bacterial bioluminescence by long-chain fatty acids (1980) (2)
Aglow in the Dark: The Revolutionary Science of Biofluorescence.ByVincent Pieriboneand, David F Gruber.Belknap Press. Cambridge (Massachusetts): Harvard University Press.$24.95. xii + 263 p; ill.; index. ISBN: 0–674–01921–0. 2005. (2006) (1)
A novel Voltage Gated Proton Channel in a Dinoflagellate (2011) (1)
Properties and cellular localization of a luciferin binding protein in the bioluminescence reaction of Gonyaulax polyedra. (1989) (1)
Bacterial Bioluminescence Light Emission in the Mixed Function Oxidation of Reduced Flavin and Fatty Aldehyde (1978) (1)
In memoriam Yata Haneda (1995) (1)
Chapter three. FIREFLIES AND OTHER BEETLES Luciferase- Dependent Bioluminescence Color and Rhythmic Displays (2012) (1)
Chapter one. A MARINE CRUSTACEAN Bioluminescent Fishes as Plagiarists and Thieves (2012) (1)
Mobilization of cloned luciferase genes into Vibrio harveyi luminescence mutants (2004) (1)
Quorum Sensing Is Not a Misnomer (2010) (1)
The Selectivity Filter of Voltage Gated Proton Channels is an Aspartate in the S1 Transmembrane Domain (2012) (0)
Crossreactivity between thelight-emitting systems ofdistantly related organisms: Noveltypeoflight-emitting compound (bioluminescence/dinoflagellate/ euphausid/luciferin/luciferase) (1980) (0)
BEATRICE M. SWEENEY August 11, 1914-July 17, 1989 (1991) (0)
Chapter four. DINOFLAGELLATES AND KRILL The Sparkling Clocks of the Oceans and Bioluminescent Shrimp (2012) (0)
Recharging the Phylogenetic Analysis of Voltage Sensor Domains (2012) (0)
The Red Absorbing Flavin Species in the Reaction of Bacterial Luciferase with FMNH2 and O2 (1981) (0)
Translational Control in the Circadian Regulation of Luminescence in the Unicellular Dinoflagellate Gonyaulax polyedra (1993) (0)
Molecular Biology and Biochemical Mechanisms of Marine Microorganisms. (1998) (0)
lnhibitors of Serine / Threonine Phosphoprotein Phosphatases , Alter Circadian Properties in Conyaulax polyedra ' (2002) (0)
Module Preview (2006) (0)
PROGRESS, PERSPECTIVES AND PROBLEMS IN BASIC ASPECTS OF BIOLUMINESCENCE (2008) (0)
Photobiology of Aneural Organisms (1981) (0)
Outlines of Enzyme Chemistry. J. B. Neilands , Paul K. Stumpf (1955) (0)
Colin stephenson pittendrigh: A memoir (2006) (0)
Biochemical mechanisms involved in biological rhythms and cycles. (1970) (0)
Structure of the oxygen adduct intermediate in the bacterial luciferase reaction : 13 C nuclear magnetic resonance determination * ( subzero temperature / oxidation-reduction / substituted flavins / flavoproteins ) (0)
Rhythmic Phenomena in Plants. B. M. Sweeney. Academic Press, New York, 1969. x + 148 pp., illus. $7. Experimental Botany, vol. 3 (1969) (0)
Structure of the oxygen adduct intermediate in the bacterial luciferase reaction: 13C nuclear magnetic resonance (0)
Chapter ten. APPLICATIONS Tools for Biology, Medicine, and Public Health (2012) (0)
A Symposium on Bioluminescence and Chemiluminescence. (1998) (0)
Light - Initiated Bioluminescence (1967) (0)
Project Seafarer (1976) (0)
Gordon Research Conference on Chronobiology, 1991 (1992) (0)
Crossreactivity between the light-ei related organisms: Novel type of lig) (bioluminescence/dinoflagellate/euphausid/luciferin/luciferase) (2016) (0)
chapter seven BIOLUMINESCENCE IN THE OCEANS Anglerfish, Dragonfish, and a Lake Baikal Parenthesis (2012) (0)
Luminescent bacterial endosymbionts in bioluminescent tunicates (2021) (0)
Molecular Biology and Genetic Regulation in Marine Dinoflagelletes (1989) (0)
Proteolytic sensitivity of the α subunit in luciferases ofPhotobacterium species (1979) (0)
chapter nine THE ORIGINS AND EVOLUTION OF BIOLUMINESCENCE How Did Luciferases Originate (2012) (0)
EVOLUTION OF BIOLUMINESCENCE IN MARINE DINOFLAGELLATES (2000) (0)
Crystal structure of a luciferase domain from the dinoflagellate Lingulodinium polyedrum (2005) (0)
The Mechanism of the Gonyaulax (Lingulodinium) Circadian Clock: Interpreting the Inputs (2005) (0)
Luminescence from biological and synthetic macromolecules. Eighth Katzir Conference. (1982) (0)
Bacterial luciferase: Bioluminescence emission using lumazines as analogs of FMN (1993) (0)
pH 14 SCIENCE: McELROY AND THE PURSUIT OF FUNDAMENTAL RESEARCH (2001) (0)
Book Review:Clinical and Biochemical Luminescence. Larry J. Kricka, Timothy J. N. Carter, Morton K. Schwartz, Thomas Whitehead (1984) (0)
Abstracts in Bioluminescence and Chemiluminescence (1982) (0)
HETEROGENEITY OF CHLOROPLAST GAPDH GENES IN THE DINOPHYCEAE (2000) (0)
chapter eight THE MANY FUNCTIONS OF BIOLUMINESCENCE Defense, Offense, Communication, and Propagation (2012) (0)
Clayton News, 12-15-1922 (2019) (0)
Singularity in a Unicell: Can Pulses of Protein Synthesis Inhibitors Stop the Biological Clock? (1985) (0)
Chapter eleven. HOW DOES LIFE MAKE LIGHT? “Excited Molecules” and Bioluminescence (2012) (0)
Letter from J. W. Hastings to Joshua Lederberg (1975) (0)
Isolation and characterization of the transient , luciferase-bound flavin-4 a-hydroxide in the bacterialluciferase reaction (2008) (0)
Photoexcited bacterial bioluminescence. Identity and properties of the photoexcitable luciferase. (1975) (0)
Antiluciferase Immunogold Labeling of two Different Organelles in the Marine Dinoflagellate Gonyrulrx Polyedra (1988) (0)
Biochemistry of biological clocks. (1973) (0)
Medium mediated effects on circadian period provide circumstantial evidence for communication in gonyaulax cultures (1985) (0)
Correction (2017) (0)
Circadian regulation of bioluminescence in Gonyaulax involves (2016) (0)
Molecular Probes in Marine Ecology: Concepts, Techniques and Applications (1990) (0)
Chapter 16 Keeping in tune with time: entrainment of circadian rhythms (2001) (0)
Poising oftheArginine PoolandControl ofBioluninescence inBeneckea harveyi (1979) (0)
Chapter six. SHORT ACCOUNTS OF OTHER LUMINOUS ORGANISMS Having different and not well- characterized biochemistries (2012) (0)
Chapter two. JELLYFISH AND GREEN FLUORESCENT PROTEIN A Soft Coral, a Calcium- Sensitive Protein, and Fish with Related Bioluminescence Systems (2012) (0)
The Kinetic Basis of Molecular Biology. Frank H. Johnson , Henry Eyring , Milton J. Polissar (1955) (0)
pH REGULATION OF LUCIFERASE ACTIVITY IN DINOFLAGELLATES INVOLVES A NOVEL ENZYMATIC MECHANISM (2005) (0)
Bioluminescence and chemiluminescence: Basic chemistry and analytical applications: edited by Marlene DeLuca, Academic Press, Inc. 1981. $44.00 (xxviii + 782 pages) ISBN 0 12 208820 4 (1982) (0)
Chapter five. BACTERIA Bacterial “Communication,” Symbioses, and Milky Seas (2012) (0)

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