Period circadian protein homolog 1

Last updated
PER1
PER1 .png
Available structures
PDB Ortholog search: PDBe RCSB
Identifiers
Aliases PER1 , PER, RIGUI, hPER, period circadian clock 1, period circadian regulator 1
External IDs OMIM: 602260 MGI: 1098283 HomoloGene: 1966 GeneCards: PER1
Orthologs
SpeciesHumanMouse
Entrez

5187

18626

Ensembl

ENSG00000179094

ENSMUSG00000020893

UniProt

O15534

O35973

RefSeq (mRNA)

NM_002616

NM_001159367
NM_011065

RefSeq (protein)

NP_002607

NP_001152839
NP_035195

Location (UCSC) Chr 17: 8.14 – 8.16 Mb Chr 11: 68.99 – 69 Mb
PubMed search [3] [4]
Wikidata
View/Edit Human View/Edit Mouse

Period circadian protein homolog 1 is a protein in humans that is encoded by the PER1 gene. [5]

Contents

Function

The PER1 protein is important to the maintenance of circadian rhythms in cells, and may also play a role in the development of cancer. This gene is a member of the period family of genes. It is expressed with a daily oscillating circadian rhythm, or an oscillation that cycles with a period of approximately 24 hours. PER1 is most notably expressed in the region of the brain called the suprachiasmatic nucleus (SCN), which is the primary circadian pacemaker in the mammalian brain. PER1 is also expressed throughout mammalian peripheral tissues. [6] Genes in this family encode components of the circadian rhythms of locomotor activity, metabolism, and behavior. Circadian expression of PER1 in the suprachiasmatic nucleus will free-run in constant darkness, meaning that the 24-hour period of the cycle will persist without the aid of external light cues. Subsequently, a shift in the light/dark cycle evokes a proportional shift of gene expression in the suprachiasmatic nucleus. The time of gene expression is sensitive to light, as light during a mammal's subjective night results in a sudden increase in per expression and thus a shift in phase in the suprachiasmatic nucleus. [7] Alternative splicing has been observed in this gene; however, these variants have not been fully described. [8] There is some disagreement between experts over the occurrence of polymorphisms with functional significance. Many scientists state that there are no known polymorphisms of the human PER1 gene with significance at a population level that results in measurable behavioral or physiological changes. [9] Still, some believe that even silent mutations can cause significant behavioral phenotypes, and result in major phase changes. [10]

Functional conservation of the PER gene is shown in a study by Shigeyoshi et al. 2002. In this study, mouse mPer1 and mPer2 genes were driven by Drosophila timeless promoter in Drosophila melanogaster. They found that both mPer constructs could restore rhythm to arrhythmic flies (per01 flies). Thus mPer1 and mPer2 can function as clock components in flies and may have implications concerning the homology of per genes. [11]

Role in chronobiology

The PER1 gene, also called rigui, is a characteristic circadian oscillator. PER1 is rhythmically transcribed in the SCN, keeping a period of approximately 24 hours. This rhythm is sustained in constant darkness, and can also be entrained to changing light cycles. [5] PER1 is involved in generating circadian rhythms in the SCN, and also has an effect on other oscillations throughout the body. For example, PER1 knockouts affect food entrainable oscillators and methamphetamine-sensitive circadian oscillators, whose periods are altered in the absence of PER1. [12] In addition, mice with knockouts in both the PER1 and PER2 genes show no circadian rhythmicity. [13] Phase shifts in PER1 neurons can be induced by a strong, brief light stimulus to the SCN of rats. This light exposure causes increases in PER1 mRNA, suggesting that the PER1 gene plays an important role in entrainment of the mammalian biological clock to the light-dark cycle. [14]

Feedback mechanism

The PER1 mRNA is expressed in all cells, acting as a part of a transcription-translation negative feedback mechanism, which creates a cell autonomous molecular clock. PER1 transcription is regulated by protein interactions with its five E-box and one D-box elements in its promoter region. Heterodimer CLOCK-BMAL1 activates E-box elements present in the PER1 promoter, as well activating the E box promoters of other components of the molecular clock such as PER2, CRY1, and CRY2. The phase of PER1 mRNA expression varies between tissues, [15] The transcript leaves the nucleus and is translated into a protein with PAS domains, which enable protein-protein interactions. PER1 and PER2 are phosphorylated by CK1ε, which leads to increased ubiquitylation and degradation. [16] This phosphorylation is counteracted by PP1 phosphatase, resulting in a more gradual increase in phosphorylated PER, and an additional control over the period of the molecular clock. [17] Phosphorylation of PER1 can also lead to masking of its leucine-rich nuclear localization sequence and thus impeded heterodimer import. [18]

PER interacts with other PER proteins as well as the E-box regulated, clock controlled proteins CRY1 and CRY2 to create a heterodimer which translocates into the nucleus. There it inhibits CLOCK-BMAL activation. [19] PER1 is not necessary for the creation circadian rhythms, but homozygous PER1 mutants display a shortened period of mRNA expression. [13] While PER1 must be mutated in conjunction with PER2 to result in arhythmiticity, the two translated PER proteins have been shown to have slightly different roles, as PER1 acts preferentially through interaction with other clock proteins. [20]

Clinical significance

PER1 expression may have significant effects on the cell cycle. Cancer is often a result of unregulated cell growth and division, which can be controlled by circadian mechanisms. Therefore, a cell's circadian clock may play a large role in its likelihood of developing into a cancer cell. PER1 is a gene that plays an important role in such a circadian mechanism. Its overexpression, in particular, causes DNA-damage induced apoptosis. In addition, down-regulation of PER1 can enhance tumor growth in mammals. [21] PER1 also interacts with proteins ATM and Chk2. These proteins are key checkpoint proteins in the cell cycle. [22] Cancer patients have a lowered expression of per1. Gery, et al. suggests that regulation of PER1 expression may be useful for cancer treatment in the future. [23]

Gene

Orthologs

The following is a list of some orthologs of the PER1 gene in other species: [24]

  • PER1 (Rattus norvegicus)
  • PER1 (Mus musculus)
  • per1a (Danio rerio)
  • PER1 (Homo sapiens)
  • lin-42 (Caenorhabditis elegans)
  • PER1 (Bos taurus)
  • per1b (Danio rerio)
  • PER (Drosophila melanogaster)
  • PER1 (Xenopus tropicalis)
  • PER1 (Equus caballus)
  • PER1 (Macaca mulatta)
  • PER1 (Sus scrofa)

Paralogs

Location

The human PER1 gene is located on chromosome 17 at the following location: [25]

PER1 has 19 transcripts (splice variants).

Discovery

The PER1 ortholog was first discovered by Ronald Konopka and Seymour Benzer in 1971. During 1997, Period 1 (mPer1) and Period 2 (mPer2) genes were discovered (Sun et al., 1997 and Albretch et al., 1997). Through homology screens with the Drosophila per, these genes were discovered. It was independently discovered by Sun et al. 1997, naming it RIGUI and by Tei et al. 1997, who named it hper because of the protein sequence similarity with Drosophila per. They found that the mouse homolog had the properties of a circadian regulator. It had circadian expression in the suprachiasmatic nucleus (SCN), self-sustained oscillation, and entrainment of circadian expression by external light cues. [26]

Related Research Articles

<span class="mw-page-title-main">Circadian rhythm</span> Natural internal process that regulates the sleep-wake cycle

A circadian rhythm, or circadian cycle, is a natural oscillation that repeats roughly every 24 hours. Circadian rhythms can refer to any process that originates within an organism and responds to the environment. Circadian rhythms are regulated by a circadian clock whose primary function is to rhythmically co-ordinate biological processes so they occur at the correct time to maximise the fitness of an individual. Circadian rhythms have been widely observed in animals, plants, fungi and cyanobacteria and there is evidence that they evolved independently in each of these kingdoms of life.

<span class="mw-page-title-main">Suprachiasmatic nucleus</span> Part of the brains hypothalamus

The suprachiasmatic nucleus or nuclei (SCN) is a small region of the brain in the hypothalamus, situated directly above the optic chiasm. The SCN is the principal circadian pacemaker in mammals, responsible for generating circadian rhythms. Reception of light inputs from photosensitive retinal ganglion cells allow the SCN to coordinate the subordinate cellular clocks of the body and entrain to the environment. The neuronal and hormonal activities it generates regulate many different body functions in an approximately 24-hour cycle.

<span class="mw-page-title-main">CREB</span> Class of proteins

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Timeless (tim) is a gene in multiple species but is most notable for its role in Drosophila for encoding TIM, an essential protein that regulates circadian rhythm. Timeless mRNA and protein oscillate rhythmically with time as part of a transcription-translation negative feedback loop involving the period (per) gene and its protein.

Period (per) is a gene located on the X chromosome of Drosophila melanogaster. Oscillations in levels of both per transcript and its corresponding protein PER have a period of approximately 24 hours and together play a central role in the molecular mechanism of the Drosophila biological clock driving circadian rhythms in eclosion and locomotor activity. Mutations in the per gene can shorten (perS), lengthen (perL), and even abolish (per0) the period of the circadian rhythm.

<span class="mw-page-title-main">PER3</span> Protein and coding gene in humans

The PER3 gene encodes the period circadian protein homolog 3 protein in humans. PER3 is a paralog to the PER1 and PER2 genes. It is a circadian gene associated with delayed sleep phase syndrome in humans.

<span class="mw-page-title-main">PER2</span> Protein-coding gene in the species Homo sapiens

PER2 is a protein in mammals encoded by the PER2 gene. PER2 is noted for its major role in circadian rhythms.

<span class="mw-page-title-main">ARNTL2</span> Protein-coding gene in humans

Aryl hydrocarbon receptor nuclear translocator-like 2, also known as Arntl2, Mop9, Bmal2, or Clif, is a gene.

In molecular biology, an oscillating gene is a gene that is expressed in a rhythmic pattern or in periodic cycles. Oscillating genes are usually circadian and can be identified by periodic changes in the state of an organism. Circadian rhythms, controlled by oscillating genes, have a period of approximately 24 hours. For example, plant leaves opening and closing at different times of the day or the sleep-wake schedule of animals can all include circadian rhythms. Other periods are also possible, such as 29.5 days resulting from circalunar rhythms or 12.4 hours resulting from circatidal rhythms. Oscillating genes include both core clock component genes and output genes. A core clock component gene is a gene necessary for to the pacemaker. However, an output oscillating gene, such as the AVP gene, is rhythmic but not necessary to the pacemaker.

Joseph S. Takahashi is a Japanese American neurobiologist and geneticist. Takahashi is a professor at University of Texas Southwestern Medical Center as well as an investigator at the Howard Hughes Medical Institute. Takahashi's research group discovered the genetic basis for the mammalian circadian clock in 1994 and identified the Clock gene in 1997. Takahashi was elected to the National Academy of Sciences in 2003.

Steven M. Reppert is an American neuroscientist known for his contributions to the fields of chronobiology and neuroethology. His research has focused primarily on the physiological, cellular, and molecular basis of circadian rhythms in mammals and more recently on the navigational mechanisms of migratory monarch butterflies. He was the Higgins Family Professor of Neuroscience at the University of Massachusetts Medical School from 2001 to 2017, and from 2001 to 2013 was the founding chair of the Department of Neurobiology. Reppert stepped down as chair in 2014. He is currently distinguished professor emeritus of neurobiology.

Michael Menaker, 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, and locating a circadian oscillator in the pineal gland of bird. He wrote almost 200 scientific publications.

Ueli Schibler is a Swiss biologist, chronobiologist and a professor at the University of Geneva. His research has contributed significantly to the field of chronobiology and the understanding of circadian clocks in the body. Several of his studies have demonstrated strong evidence for the existence of robust, self-sustaining circadian clocks in the peripheral tissues.

Hitoshi Okamura is a Japanese scientist who specializes in chronobiology. He is currently a professor of Systems Biology at Kyoto University Graduate School of Pharmaceutical Sciences and the Research Director of the Japan Science Technology Institute, CREST. Okamura's research group cloned mammalian Period genes, visualized clock oscillation at the single cell level in the central clock of the SCN, and proposed a time-signal neuronal pathway to the adrenal gland. He received a Medal of Honor with Purple Ribbon in 2007 for his research and was awarded Aschoff's Ruler for his work on circadian rhythms in rodents. His lab recently revealed the effects of m6A mRNA methylation on the circadian clock, neuronal communications in jet lag, and the role of dysregulated clocks in salt-induced hypertension.

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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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<span class="mw-page-title-main">Sato Honma</span>

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