The human per1 gene: genomic organization and promoter analysis of the first human orthologue of the Drosophila period gene

Sleep-wake disorders in Alzheimer's disease: further genetic analyses in relation to objective sleep measures

This paper presents updated analyses on the genetic associations of sleep disruption in individuals with Alzheimer's disease (AD). We published previously a study of the association between single nucleotide polymorphisms (SNPs) found in eight genes related to circadian rhythms and objective measures of sleep-wake disturbances in 124 individuals with AD. Here, we present new relevant analyses using polygenic risk scores (PRS) and variable number tandem repeats (VNTRs) enumerations. PRS were calculated using the genetic data from the original participants and relevant genome wide association studies (GWAS). VNTRs for the same circadian rhythm genes studied with SNPs were obtained from a separate cohort of participants using whole genome sequencing (WGS). Objectively (wrist actigraphy) determined wake after sleep onset (WASO) was used as a measure of sleep disruption. None of the PRS were associated with sleep disturbance. Computer analyses using VNTRseek software generated a total of 30 VNTRs for the circadian-related genes but none appear relevant to our objective sleep measure. In addition, of 71 neurotransmitter function-related genes, 29 genes had VNTRs that differed from the reference VNTR, but it was not clear if any of these might affect circadian function in AD patients. Although we have not found in either the current analyses or in our previous published analyses of SNPs any direct linkages between identified genetic factors and WASO, research in this area remains in its infancy.

Histone deacetylase inhibitors induce the expression of tumor suppressor genes Per1 and Per2 in human gastric cancer cells

Period circadian regulator (Per)1 and Per2 genes are involved in the molecular mechanism of the circadian clock, and exhibit tumor suppressor properties. Several studies have reported a decreased expression of Per1, Per2 and Per3 genes in different types of cancer and cancer cell lines. Promoter methylation downregulates Per1, Per2 or Per3 expression in myeloid leukemia, breast, lung, and other cancer cells; whereas histone deacetylase inhibitors (HDACi) upregulate Per1 or Per3 expression in certain cancer cell lines. However, the transcriptional regulation of Per1 and Per2 in cancer cells by chromatin modifications is not fully understood. The present study aimed to determine whether HDACi regulate Per1 and Per2 expression in gastric cancer cell lines, and to investigate changes in chromatin modifications in response to HDACi. Treatment of KATO III and NCI-N87 human gastric cancer cells with sodium butyrate (NaB) or Trichostatin A (TSA) induced Per1 and Per2 mRNA expression in a dose-dependent manner. Chromatin immunoprecipitaion assays revealed that NaB and TSA decreased lysine 9 trimethylation on histone H3 (H3K9me3) at the Per1 promoter. TSA, but not NaB increased H3K9 acetylation at the Per2 promoter. It was also observed that binding of Sp1 and Sp3 to the Per1 promoter decreased following NaB treatment, whereas Sp1 binding increased at the Per2 promoter of NaB- and TSA-treated cells. In addition, Per1 promoter is not methylated in KATO III cells, while Per2 promoter was methylated, although NaB, TSA, and 5-Azacytidine do not change the methylated CpGs analyzed. In conclusion, HDACi induce Per1 and Per2 expression, in part, through mechanisms involving chromatin remodeling at the proximal promoter of these genes; however, other indirect mechanisms triggered by these HDACi cannot be ruled out. These findings reveal a previously unappreciated regulatory pathway between silencing of Per1 gene by H3K9me3 and upregulation of Per2 by HDACi in cancer cells.

Peripheral circadian clocks are diversely affected by adrenalectomy

Glucocorticoids are considered to synchronize the rhythmicity of clock genes in peripheral tissues; however, the role of circadian variations of endogenous glucocorticoids is not well defined. In the present study, we examined whether peripheral circadian clocks were impaired by adrenalectomy. To achieve this, we tested the circadian rhythmicity of core clock genes (Bmal1, Per1-3, Cry1, RevErbα, Rora), clock-output genes (Dbp, E4bp4) and a glucocorticoid- and clock-controlled gene (Gilz) in liver, jejunum, kidney cortex, splenocytes and visceral adipose tissue (VAT). Adrenalectomy did not affect the phase of clock gene rhythms but distinctly modulated clock gene mRNA levels, and this effect was partially tissue-dependent. Adrenalectomy had a significant inhibitory effect on the level of Per1 mRNA in VAT, liver and jejunum, but not in kidney and splenocytes. Similarly, adrenalectomy down-regulated mRNA levels of Per2 in splenocytes and VAT, Per3 in jejunum, RevErbα in VAT and Dbp in VAT, kidney and splenocytes, whereas the mRNA amounts of Per1 and Per2 in kidney and Per3 in VAT and splenocytes were up-regulated. On the other hand, adrenalectomy had minimal effects on Rora and E4bp4 mRNAs. Adrenalectomy also resulted in decreased level of Gilz mRNA but did not alter the phase of its diurnal rhythm. Collectively, these findings suggest that adrenalectomy alters the mRNA levels of core clock genes and clock-output genes in peripheral organs and may cause tissue-specific modulations of their circadian profiles, which are reflected in changes of the amplitudes but not phases. Thus, the circulating corticosteroids are necessary for maintaining the high-amplitude rhythmicity of the peripheral clocks in a tissue-specific manner.

ETV6 fusion genes in hematological malignancies: a review

Translocations involving band 12p13 are one of the most commonly observed chromosomal abnormalities in human leukemia and myelodysplastic syndrome. Their frequently result in rearrangements of the ETV6 gene. At present, 48 chromosomal bands have been identified to be involved in ETV6 translocations, insertions or inversions and 30 ETV6 partner genes have been molecularly characterized. The ETV6 protein contains two major domains, the HLH (helix-loop-helix) domain, encoded by exons 3 and 4, and the ETS domain, encoded by exons 6 through 8, with in between the internal domain encoded by exon 5. ETV6 is a strong transcriptional repressor, acting through its HLH and internal domains. Five potential mechanisms of ETV6-mediated leukemogenesis have been identified: constitutive activation of the kinase activity of the partner protein, modification of the original functions of a transcription factor, loss of function of the fusion gene, affecting ETV6 and the partner gene, activation of a proto-oncogene in the vicinity of a chromosomal translocation and dominant negative effect of the fusion protein over transcriptional repression mediated by wild-type ETV6. It is likely that ETV6 is frequently involved in leukemogenesis because of the large number of partners with which it can rearrange and the several pathogenic mechanisms by which it can lead to cell transformation.

Circadian phosphorylation of ATF-2, a potential activator of Period2 gene transcription in the chick pineal gland

Stimulus-induced transcription of the Period gene is a critical step for phase-shift of vertebrate circadian systems. The promoter region of chicken Period2 contains a canonical calcium/cAMP-responsive element, but its functional relevance is not known. The present study shows that cAMP-responsive element-binding protein (CREB) and activating transcription factor-2 (ATF-2) bind to the promoter region of the Period2 gene in the chick pineal gland. In transient transfection assays, a reporter construct containing 0.7-kbp upstream region of chicken Period2 was transactivated by ATF-2, but it was poorly responsive to CREB. In the chick pineal gland, phosphorylation of CREB protein at the kinase-inducible domain was negatively regulated by light. On the other hand, phosphorylation of ATF-2 at the amino-terminal transactivation domain exhibited a circadian rhythm with a daytime peak, suggesting a role for ATF-2 in circadian rhythmicity in the chick pineal gland.

Uncoupling of promoter methylation and expression of Period1 in cervical cancer cells

We investigated possible epigenetic regulation of Period1 (PER1), a key circadian regulator gene, in six cervical cancer cell lines which showed up to 15.4-fold differences in PER1 mRNA levels. Genomic methylation analysis showed that a discerned CpG island in the PER1 promoter remained hypomethylated in five of the cell lines. In contrast, C33A cells that showed maximal PER1 expression was hypermethylated; however, demethylation treatment of C33A cells resulted in small but significant elevated PER1 mRNA levels suggesting a secondary role for promoter hypermethylation in PER1 transcriptional regulation. A discerned hypomethylated zone that harbours crucial transcriptional elements including the critical proximal E-box progressively diminished in size in the cell lines until a methylation-resistant core was retained in C33A. Our data indicate that PER1 transcription is mainly uncoupled from promoter methylation but probably involves availability and interactions of trans-acting factors with differentially methylated cis elements in the promoter hypomethylated zone.

Activation of human period-1 by PKA or CLOCK/BMAL1 is conferred by separate signal transduction pathways

Circadian clocks are self-sustained biochemical oscillators that autonomously generate a near-24 h cycle in the absence of external signals. The process of synchronization to the environment involves the transcriptional activation of several genes. Photic input signals from the retina are transduced via the retinohypothalamic tract to the central pacemaker located in the suprachiasmatic nuclei (SCN) of the hypothalamus. It is known that cells of peripheral organs possess similar molecular organizations, but the signal transductional pathways lack direct light entrainment. It has been assumed that the adaptation of peripheral organs to the SCN phase is achieved by the alternate usage of promoter elements. This question has been addressed by characterizing the signal transductional pathways regulating human Period-1 gene expression in human hepatoma cells (HuH-7). Plasmids coding for key modulators of circadian rhythm, hCLOCK, hBMAL1, and hCRY2 were used to analyze the activation of a human period-1 promoter luciferase (hPER1-luc) construct. Beside classical CLOCK/BMAL1 activation, hPER1-luc was also inducible by the overexpression of the catalytic subunit of PKA (Calpha). The cotransfection of dominant negative constructs to c-FOS, CREB, PKA, and C/EBP were used to characterize both regulatory pathways. It was found that hCLOCK/hBMAL1-mediated hPER1 activation was influenced by AP1, but not significantly by other regulators. Conversely, PKA-induced activation of hPER1 was reduced by the inhibition of CREB and the CCAAT-box binding protein C/EBP, but not by AP1. The present findings imply that CLOCK/BMAL1-mediated activation of hPER1 by AP1 and E-Box elements is distinct from peripheral transcriptional modulation via cAMP-induced CREB and C/EBP.

A silent polymorphism in the PER1 gene associates with extreme diurnal preference in humans

The three PERIOD proteins form a major negative feedback component of the molecular mechanism governing the periodicity of the vertebrate circadian clock. Genetic variations within the human PER2 and PER3 genes have been linked with diurnal preference and disorders of sleep timing. We screened the coding region of PER1, as well as the 5'- and 3'-untranslated regions and the promoter region, for polymorphisms. The T2434C polymorphism in exon 18, a synonymous substitution, associated with extreme diurnal preference. The C allele was more frequent in subjects with extreme morning preference (frequency=0.24) than in subjects with extreme evening preference (frequency=0.12). No significant association was observed between either allele and delayed sleep phase syndrome. This polymorphism may have a direct effect on RNA translatability, or be in linkage disequilibrium with another polymorphism which affects PER1 expression at the DNA, RNA, or protein level. This is the first reported association between a PER1 polymorphism and extreme diurnal preference. Functionally important polymorphisms in PER1 are rare, which may indicate that it is subject to more stringent selection pressure than the other PER genes.

Early transcriptional effects of aldosterone in a mouse inner medullary collecting duct cell line

The mineralocorticoid aldosterone is a major regulator of Na+ and acid-base balance and control of blood pressure. Although the long-term effects of aldosterone have been extensively studied, the early aldosterone-responsive genes remain largely unknown. Using DNA array technology, we have characterized changes in gene expression after 1 h of exposure to aldosterone in a mouse inner medullary collecting duct cell line, mIMCD-3. Results from three independent microarray experiments revealed that the expression of many transcripts was affected by aldosterone treatment. Northern blot analysis confirmed the upregulation of four distinct transcripts identified by the microarray analysis, namely, the serum and glucose-regulated kinase sgk, connective tissue growth factor, period homolog, and preproendothelin. Immunoblot analysis for preproendothelin demonstrated increased protein expression. Following the levels of the four transcripts over time showed that each had a unique pattern of expression, suggesting that the cellular response to aldosterone is complex. The results presented here represent a novel list of early aldosterone-responsive transcripts and provide new avenues for elucidating the mechanism of acute aldosterone action in the kidney.

Oscillation of human period 1 (hPER1) reporter gene activity in human neuroblastoma cells in vivo

The mammalian period (Per) genes, which are components of the circadian clock, are mainly regulated via an autoregulatory feedback loop. Here we provide evidence that human Per1 (hPER1) reporter gene activity shows circadian rhythmicity in a human neuroblastoma, but not in a astrocytoma or a hepatoma cell line. Medium change and various pharmacological stimuli differentially induce this behavior. This circadian oscillation was strongly dampened and could be followed over maximally three cycles. It was even possible to phase-shift the course of this oscillation by repeated application of stimuli.

A novel cryptic translocation t(12;17)(p13;p12-p13) in a secondary acute myeloid leukemia results in a fusion of the ETV6 gene and the antisense strand of the PER1 gene

The ETV6 gene is a member of the ETS family of transcription factors and the main target of chromosomal rearrangements affecting chromosome band 12p13. To date, more than 15 fusion partners of ETV6 have been characterized at the molecular level. Most of these fusions encode chimeric proteins with oncogenic properties. However, some of the translocations do not produce a functional fusion protein, but may induce ectopic expression of oncogenes located close to the breakpoint. We herein report the characterization and cloning of a novel cryptic translocation, t(12;17)(p13;p12-p13), occurring in a patient with an acute myeloid leukemia evolving from a chronic myelomonocytic leukemia. Cytogenetic analysis suggested the presence of a deletion of the short arm of chromosome 12, del(12)(p13), in three of the five metaphase cells analyzed. However, fluorescence in situ hybridization (FISH) with the ETV6-specific cosmid clones 179A6, 50F4, 163E7, and 148B6 as well as probes hybridizing to the TP53 gene on 17p13 and the subtelomeric region of 17p revealed the presence of a translocation between 12p and 17p. By FISH, the breakpoints could be localized in intron 1 of ETV6 and centromeric to TP53. By 3' rapid amplification of cDNA ends-polymerase chain reaction (3' RACE-PCR), a fusion transcript between exon 1 of ETV6 and the antisense strand of PER1 (period homolog 1, Drosophila), a circadian clock gene, could be identified. This ETV6-PER1 (antisense PER1 strand) fusion transcript does not produce a fusion protein, and no other fusion transcripts could be detected. We hypothesize that in the absence of a fusion protein, the inactivation of PER1 or deregulation of a gene in the neighborhood of PER1 may contribute to the pathogenesis of leukemias with a t(12;17)(p13;p12-p13).

Structural and functional analysis of 3' untranslated region of mouse Period1 mRNA

In order to investigate the post-transcriptional regulation of Period1 (Per1), the 3(')-untranslated region (3(')UTR) of mouse Per1 (mPer1) mRNA was characterized. In addition to high similarity between human and mouse Per1 3(')UTRs, AU-rich element and differentiation control element were found in both species. Transient transfection assays using LUC::mPer1 3(')UTR fusion genes revealed that the mPer1 3(')UTR repressed its own expression in a post-transcriptional manner. The region critical for this translational down-regulation was confined to nucleotide positions 322-517. These results suggest that the mPer1 3(')UTR could be involved in the generation of time lag between the transcriptional and translational products of mPer1 in the suprachiasmatic nucleus.

The influence of heredity on self-reported sleep patterns in free-living humans

The heritability of self-reported sleep patterns was investigated with 86 identical and 78 fraternal same-sex and 51 fraternal mixed-gender adult twin pairs who were paid to maintain 7-day diaries. Linear structural modeling was applied to investigate the nature and degree of genetic and environmental influences and revealed significant genetic influences on the time that individuals went to sleep and woke up, how often the individual woke up during the night, the duration of sleep and wakefulness, and how alert the individual felt upon waking and over the day, accounting for 21% to 41% of the variance. These influences of heredity were present for sleep-wake behavior over the entire week and also when the sleep-wake pattern was analyzed separately for weekdays and weekends. Further, it was demonstrated that there were multiple independent influences of heredity on sleep-wake behavior. The results suggest that sleep-wake patterns are not learned but result in part from multiple heritable influences.

The human PER1 gene is inducible by interleukin-6

The mammalian period (Per) genes which are components of the circadian clock are mainly regulated via an autoregulatory feedback loop. Here we show that a human PER1 (hPER1) reporter gene activity is stimulated by interleukin-6 (IL-6), a member of the large cytokine gene family and an inducer of the acute phase reaction, in human hepatoma (HuH-7) cells. Our results confirm and extend the view that the hPER1 promoter acts as a sensor for multiple signaling molecules thereby integrating different physiological parameters.

Human clock genes

Rhythmic variations in physiological and behavioural processes are mediated by both endogenous and exogenous factors. Endogenous factors include self-sustaining biological pacemakers or clocks which in the absence of strong external influences self-sustain periodic rhythms in such diverse physiological and psychological processes as core body temperature, food intake, cognitive performance and mood. Clocks with endogenous periods near or at 24 h (called circadian clocks from the Latin, circa dies, meaning about one day) have been documented from prokaryotes to single cell eukaryotes to multi-cellular, complex animals such as flies, rodents and humans. Over the past few years, a revolution in the understanding of the molecular basis of these clocks has led to the identification of a number of core clock genes and their proteins, and the development of elegant feedback models to explain the molecular gears of circadian clocks. At least eight human orthologs of mouse core clock genes have been identified, and polymorphisms in two of these, hClock and hPer2, have been implicated in human sleep disorders. Remarkably, knowledge of these core clock genes and the development of sophisticated reporter systems to monitor clock gene promoter activity have led to the astonishing observation that our body is actually composed of millions of cellular clocks and oscillators whose co-ordinated activity gives rise to pronounced daily, monthly, and seasonal rhythms in physiology and behaviour. An idea that is gaining favour is that our physical and mental well-being is probably determined by the appropriate phasing of these millions of cellular clocks with recurring, meaningful events in the environment.

Heritability of diurnal changes in food intake in free-living humans

OBJECTIVES

The time of day of meal ingestion, the number of people present at the meal, the subjective state of hunger, and the estimated before-meal contents in the stomach have been established as influences on the amount eaten in a meal, and this influence has been shown to be heritable. Because these factors intercorrelate, the possibility that the calculated heritabilities for some of these variables could result indirectly from their convariation with one of the other heritable variables was assessed.

METHODS

The independence of the heritability of the influence of these four factors was investigated with 110 identical and 102 fraternal same-sex and 53 fraternal mixed-sex adult twin pairs who were paid to maintain 7-d food intake diaries. From the diary reports, the meal sizes were calculated and subjected to multiple regression analysis using the estimated before-meal stomach contents, the reported number of other people present, the subjective hunger ratings, and the time of day of the meal as predictors. Linear structural modeling was applied to the beta coefficients from the multiple regression to investigate whether the heritability of the influences of these four variables was independent.

RESULTS

Significant genetic effects were found for the beta coefficients for all four variables, indicating that the heritability of their relationship with intake is to some extent heritable.

CONCLUSIONS

These results suggest that the influences of multiple factors on intake are influenced by the genes and become part of the total package of genetically determined physiologic, sociocultural, and psychological processes that regulate energy balance.

Analysis of human Per4

The molecular mechanism of the circadian pacemaker depends on the oscillatory expression of clock gene constituents. The Drosophila period gene is central to the clock mechanism in these animals. Three homologs of this gene identified in mice (mPer1-3) and humans (hPer1-3) display rhythmic expression and are important for normal clock function. Recently, analysis of the draft sequence of the human genome has revealed the presence of a fourth Per gene family member. Surprisingly, the deduced hPer4 cDNA has no open reading frame encoding a full-length PER-like protein. This sequence is characterized by numerous deletions, insertions, frame shifts and base pair changes, and its genomic structure is devoid of introns. The presence of an MER-2 mobile element fossil within the Per4 locus predicted that this gene would also be present in non-human primates. Rhesus monkey Per4 displays similar sequence anomalies and is 92.8% identical to hPer4. Sequence comparisons indicate that Per4 originated from a Per3 predecessor and that it is relatively new to the Period gene family. We conclude that hPer4 and RmPer4 are pseudogenes and descended from the retrotransposition of an ancestral Per3 gene.

Wild-type circadian rhythmicity is dependent on closely spaced E boxes in the Drosophila timeless promoter

Transcriptional regulation plays an important role in Drosophila melanogaster circadian rhythms. The period promoter has been well studied, but the timeless promoter has not been analyzed in detail. Mutagenesis of the canonical E box in the timeless promoter reduces but does not eliminate timeless mRNA cycling or locomotor activity rhythms. This is because there are at least two other cis-acting elements close to the canonical E box, which can also be transactivated by the circadian transcription factor dCLOCK. These E-box-like sequences cooperate with the canonical E-box element to promote high-amplitude transcription, which is necessary for wild-type rhythmicity.

The human PER1 gene is transcriptionally regulated by multiple signaling pathways

The mammalian period (Per) genes are components of the circadian clock and appear to be regulated via an autoregulatory feedback loop. Here we show that the human PER1 (hPER1) gene is synergistically activated by protein kinases A and C (PKA, PKC) and cAMP responsive element binding protein. Activators and inhibitors of PKA as well as PKC modulate endogenous hPER1 expression and hPER1 promoter-driven reporter gene activity in a dose-dependent manner. Our results suggest that the hPER1 promoter acts as a sensor for multiple signaling molecules thereby integrating different physiological parameters. This regulation of hPER1 appears to be significant for rapid adaptation to changing environmental conditions.