Hajime Tei | Academic Influence

Hajime Tei's AcademicInfluence.com Rankings

Hajime Tei

Biology

#15566

World Rank

#19580

Historical Rank

Neuroscience

#2897

World Rank

#2975

Historical Rank

biology Degrees

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Biology

Hajime Tei's Degrees

Bachelors Biology University of Tokyo
Masters Neuroscience Kyoto University
PhD Neuroscience Hokkaido University

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Why Is Hajime Tei Influential?

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According to Wikipedia, Hajime Tei is a Japanese neuroscientist specializing in the study of chronobiology. He currently serves as a professor at the Kanazawa University Graduate School of Natural Science & Technology. He is most notable for his contributions to the discovery of the mammalian period genes, which he discovered alongside Yoshiyuki Sakaki and Hitoshi Okamura.

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Hajime Tei'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

Resetting central and peripheral circadian oscillators in transgenic rats. (2000) (1789)
Entrainment of the circadian clock in the liver by feeding. (2001) (1626)
Light-Induced Resetting of a Mammalian Circadian Clock Is Associated with Rapid Induction of the mPer1 Transcript (1997) (850)
Circadian oscillation of a mammalian homologue of the Drosophila period gene (1997) (782)
Circadian Rhythms in Isolated Brain Regions (2002) (625)
Molecular Cloning of a Novel Human CC Chemokine Liver and Activation-regulated Chemokine (LARC) Expressed in Liver (1997) (292)
Temporal Precision in the Mammalian Circadian System: A Reliable Clock from Less Reliable Neurons (2004) (279)
Effects of aging on central and peripheral mammalian clocks (2002) (277)
Inhibition of Light- or Glutamate-Induced mPer1Expression Represses the Phase Shifts into the Mouse Circadian Locomotor and Suprachiasmatic Firing Rhythms (1999) (276)
A Calcium Flux Is Required for Circadian Rhythm Generation in Mammalian Pacemaker Neurons (2005) (173)
The human and mouse Period1 genes: five well-conserved E-boxes additively contribute to the enhancement of mPer1 transcription. (2000) (142)
A YAC contig of the human CC chemokine genes clustered on chromosome 17q11.2. (1996) (129)
LARK activates posttranscriptional expression of an essential mammalian clock protein, PERIOD1 (2007) (98)
Reorganization of the Suprachiasmatic Nucleus Coding for Day Length (2008) (98)
Molecular assembly of the period-cryptochrome circadian transcriptional repressor complex (2014) (86)
Plasticity of Circadian Behavior and the Suprachiasmatic Nucleus Following Exposure to Non-24-Hour Light Cycles (2004) (76)
Ontogeny of Circadian Organization in the Rat (2009) (74)
Bone Resorption Is Regulated by Circadian Clock in Osteoblasts (2017) (74)
Maternal Feeding Controls Fetal Biological Clock (2008) (61)
pokkuri, a Drosophila gene encoding an E-26-specific (Ets) domain protein, prevents overproduction of the R7 photoreceptor. (1992) (58)
Constitutive expression of the Period1 gene impairs behavioral and molecular circadian rhythms. (2006) (54)
Bimodal Clock Gene Expression in Mouse Suprachiasmatic Nucleus and Peripheral Tissues Under a 7-Hour Light and 5-Hour Dark Schedule (2007) (45)
The intrinsic microglial clock system regulates interleukin‐6 expression (2017) (44)
The uterus sustains stable biological clock during pregnancy. (2010) (43)
Characterization of a novel member of the FGF family, XFGF-20, in Xenopus laevis. (1999) (38)
Structural and functional analysis of 3' untranslated region of mouse Period1 mRNA. (2003) (32)
Establishment of cell lines derived from the rat suprachiasmatic nucleus. (2007) (26)
Rare Occurrence of ras and p53 Gene Mutations in Mouse Stomach Tumors Induced by N–Methyl–N–nitrosourea (1997) (24)
Specific pathogen free conditions prevent transthyretin amyloidosis in mouse models (2008) (17)
Real-Time Recording of Circadian Per1 and Per2 Expression in the Suprachiasmatic Nucleus of Freely Moving Rats (2016) (17)
Circadian mPer1 gene expression in mesencephalic trigeminal nucleus cultures (2008) (16)
Bulla gouldiana period exhibits unique regulation at the mrnA and Protein Levels (2002) (14)
Positive Autoregulation Delays the Expression Phase of Mammalian Clock Gene Per2 (2011) (12)
Co-precipitation molecules hemopexin and transferrin may be key molecules for fibrillogenesis in TTR V30M amyloidogenesis (2017) (9)
In vivo bioluminescence and reflectance imaging of multiple organs in bioluminescence reporter mice by bundled-fiber-coupled microscopy. (2016) (8)
Phosphorylation of N‐terminal regions of REV‐ERBs regulates their intracellular localization (2018) (8)
Feedback loops interlocked at competitive binding sites amplify and facilitate genetic oscillations. (2017) (6)
A saturated reaction in repressor synthesis creates a daytime dead zone in circadian clocks (2019) (6)
Phase Shifts of Circadian Transcripts in Rat Suprachiasmatic Nucleus (2008) (3)
Sequence and expression of a gene encoding a ribosomal protein S4 homolog from Drosophila melanogaster. (1993) (3)
Erratum: Plasticity of circadian behavior and the suprachiasmatic nucleus following exposure to non-24-hour light cycles (Journal of Biological Rhythms (2004) 19 (198-207)) (2004) (2)
Genetic and Molecular Analysis of Wild-Derived Arrhythmic Mice (2009) (1)
Author response: Molecular assembly of the period-cryptochrome circadian transcriptional repressor complex (2014) (1)
Nanoscale‐tipped wire array injections transfer DNA directly into brain cells ex vivo and in vivo (2022) (1)
Complementary phase responses via functional differentiation of dual negative feedback loops (2021) (0)
Feedback loops interlocked at competitive binding sites amplify genetic oscillations in mammalian circadian rhythms (2016) (0)
Analysis of transcriptional regulation of a mammalian clock gene, Rev-erbα . (2015) (0)
Neglected Reference (2004) (0)
Expression of Per1 in the hamster brain; Day-night variation and light induction in the suprachiasmatic nucleus (1998) (0)
P.1.24 A transmembrane calcium flux is requiredfor circadian clock gene rhythmicity in mammalian pacemaker neurons (2005) (0)
Functional analysis of transcriptional regulation of a mammalian clock gene, Bmal1 (2015) (0)
Crystal Structure of Mammalian Period-Cryptochrome Complex (2014) (0)
Investigation of Muscle Energy Metabolism in Diabetic Patients by 31P Nuclear Magnetic Resonance Spectroscopy (2011) (0)
Resetting Central and (2000) (0)
Cell size homeostasis under the circadian regulation of cell division in cyanobacteria (2022) (0)
CHARACTERIZATION OF POKKURI, A MUTATION AFFECTING LONGEVITY AND EYE DEVELOPMENT OF DROSOPHILA MELANOGASTER : Developmental Biology (1990) (0)
In Vivo Real-Time Monitoring of Circadian Per1 and Per2 Expression in the Rat Suprachiasmatic Nucleus (2016) (0)
Modification of REV-ERB Nuclear Receptors for Regulation of Mammalian Clock (2016) (0)
[Genetic regulation of circadian rhythms]. (2004) (0)
Co-precipitation molecules hemopexin and transferrin may be key molecules for fibrillogenesis in TTR V30M amyloidogenesis (2017) (0)
RNAi-mediated knockdown of mouse melanocortin-4 receptor in vitro and in vivo, using an siRNA expression construct based on the mir-187 precursor (2016) (0)
Mutagenization of a clock gene, Rev-erbα , in a cell line delivered from rat central circadian pacemaker SCN cells. (2016) (0)
Gastrin-releasing peptide mediates photic entrainment signaling in the suprachiasmatic nucleus via ERK1/2 activation (2009) (0)
Period-phase map: two-dimensional selection of circadian rhythm-related genes. (2009) (0)
Mechanisms underlying GRP receptor-mediated resetting of the biological clock in an immortalized rat SCN cell line (2010) (0)

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Other Resources About Hajime Tei

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What Schools Are Affiliated With Hajime Tei?

Hajime Tei is affiliated with the following schools: