Closely watched clocks: molecular analysis of circadian rhythms in Neurospora and Drosophila

Circadian rhythms represent a type of cellular regulation common to most eukaryotes. Analysis of the genetic basis of this phenomenon is beginning to provide information about how clocks function at the molecular level. Surprisingly, the first two cloned 'clock genes', one from a fruit fly and one from a fungus, share some common characteristics both genetically and in the nature of the proteins they encode. In related work, the recent identification and molecular analysis of clock-controlled genes is revealing how biological clocks control gene expression, and may pave the way for the isolation of novel 'clock genes' in the future.     

The in vitro real-time oscillation monitoring system identifies potential entrainment factors for circadian clocks

Background  

Circadian rhythms are endogenous, self-sustained oscillations with approximately 24-hr rhythmicity that are manifested in various physiological and metabolic processes. The circadian organization of these processes in mammals is governed by the master oscillator within the suprachiasmatic nuclei (SCN) of the hypothalamus. Recent findings revealed that circadian oscillators exist in most organs, tissues, and even in immortalized cells, and that the oscillators in peripheral tissues are likely to be coordinated by SCN, the master oscillator. Some candidates for endogenous entrainment factors have sporadically been reported, however, their details remain mainly obscure.     

Non-ventral lateral neuron-based, non-PDF-mediated clocks control circadian egg-laying rhythm in Drosophila melanogaster

The authors report the results of their study aimed at investigating the consequence of targeted ablation of ventral lateral neurons (LN(v)s--neurons regulating eclosion and locomotor activity rhythms) and genetic disruption of pigment-dispersing factor (PDF--an important output of circadian clocks) on the egg-laying rhythm of Drosophila melanogaster. The results clearly suggest that genetic ablation of LN(v)s and loss of function mutation of PDF abolish eclosion and locomotor activity rhythms, whereas the egg-laying rhythm continues unabated. Furthermore, the results also demonstrate that the period of egg-laying rhythm remains unchanged under different ambient temperatures and nutrition levels, suggesting that the egg-laying rhythm of D. melanogaster is temperature and nutrition compensated. Based on these results, the authors conclude that the egg-laying rhythm in D. melanogaster is regulated by non-LN(v)-based, non-PDF-mediated circadian clocks.     

Genetic encoding of non‐natural amino acids in Drosophila melanogaster Schneider 2 cells

Insect cells are useful for the high‐yield production of recombinant proteins including chemokines and membrane proteins. In this study, we developed an insect cell‐based system for incorporating non‐natural amino acids into proteins at specific sites. Three types of promoter systems were constructed, and their efficiencies were compared for the expression of the prokaryotic amber suppressor tRNA^Tyr in Drosophila melanogaster Schneider 2 cells. When paired with a variant of Escherichia coli tyrosyl‐tRNA synthetase specific for 3‐iodo‐L ‐tyrosine, the suppressor tRNA transcribed from the U6 promoter most efficiently incorporated the amino acid into proteins in the cells. The transient and stable introductions of these prokaryotic molecules into the insect cells were then compared in terms of the yield of proteins containing non‐natural amino acids, and the “transient” method generated a sevenfold higher yield. By this method, 4‐azido‐L ‐phenylalanine was incorporated into human interleukin‐8 at a specific site. The yield of the azido‐containing IL‐8 was 1 μg/1 mL cell culture, and the recombinant protein was successfully labeled with a fluorescent probe by the Staudinger–Bertozzi reaction.     

Precise circadian clocks in prokaryotic cyanobacteria

Prokaryotic cyanobacteria express robust circadian (daily) rhythms under the control of a timing mechanism that is independent of the cell division cycle. This biological clock orchestrates global regulation of gene expression and controls the timing of cell division. Proteins that may be involved in input pathways have been identified. Mutational screening has identified three clock genes that are organized as a gene cluster. The structure of cyanobacterial clock proteins, their phosphorylation, and regulation is described. A new model for the core clockwork in cyanobacteria proposes that rhythmic changes in the status of the chromosome underlie the rhythms of gene expression. Mixed-strain experiments demonstrate that this timekeeper confers adaptive value when different strains compete against each other.     

A non‐canonical function of topoisomerase II in disentangling dysfunctional telomeres

The decatenation activity of topoisomerase II (Top2), which is widely conserved within the eukaryotic domain, is essential for chromosomal segregation in mitosis. It is less clear, however, whether Top2 performs the same function uniformly across the whole genome, and whether all its functions rely on decatenation. In the fission yeast, Schizosaccharomyces pombe, telomeres are bound by Taz1, which promotes smooth replication fork progression through the repetitive telomeric sequences. Hence, replication forks stall at taz1Δ telomeres. This leads to telomeric entanglements at low temperatures (⩽20°C) that cause chromosomal segregation defects and loss of viability. Here, we show that the appearance of entanglements, and the resulting cold sensitivity of taz1Δ cells, is suppressed by mutated alleles of Top2 that confer slower catalytic turnover. This suppression does not rely on the decatenation activity of Top2. Rather, the enhanced presence of reaction intermediates in which Top2 is clamped around DNA, promotes the removal of telomeric entanglements in vivo, independently of catalytic cycle completion. We propose a model for how the clamped enzyme–DNA complex promotes proper chromosomal segregation.     

Two combinatorial patterns of telomere histone marks in plants with canonical and non‐canonical telomere repeats

Telomeres, nucleoprotein structures at the ends of linear eukaryotic chromosomes, are crucial for the maintenance of genome integrity. In most plants, telomeres consist of conserved tandem repeat units comprising the TTTAGGG motif. Recently, non‐canonical telomeres were described in several plants and plant taxons, including the carnivorous plant Genlisea hispidula (TTCAGG/TTTCAGG), the genus Cestrum (Solanaceae; TTTTTTAGGG), and plants from the Asparagales order with either a vertebrate‐type telomere repeat TTAGGG or Allium genus‐specific CTCGGTTATGGG repeat. We analyzed epigenetic modifications of telomeric histones in plants with canonical and non‐canonical telomeres, and further in telomeric chromatin captured from leaves of Nicotiana benthamiana transiently transformed by telomere CRISPR‐dCas9‐eGFP, and of Arabidopsis thaliana stably transformed with TALE_telo C‐3×GFP. Two combinatorial patterns of telomeric histone modifications were identified: (i) an Arabidopsis‐like pattern (A. thaliana, G. hispidula, Genlisea nigrocaulis, Allium cepa, Narcissus pseudonarcissus, Petunia hybrida, Solanum tuberosum, Solanum lycopersicum) with telomeric histones decorated predominantly by H3K9me2; (ii) a tobacco‐like pattern (Nicotiana tabacum, N. benthamiana, C. elegans) with a strong H3K27me3 signal. Our data suggest that epigenetic modifications of plant telomere‐associated histones are related neither to the sequence of the telomere motif nor to the lengths of the telomeres. Nor the phylogenetic position of the species plays the role; representatives of the Solanaceae family are included in both groups. As both patterns of histone marks are compatible with fully functional telomeres in respective plants, we conclude that the described specific differences in histone marks are not critical for telomere functions.     

A non‐canonical rhodopsin‐mediated insulin receptor signaling pathway in retinal photoreceptor neurons

We previously reported a ligand‐independent and rhodopsin‐dependent insulin receptor (IR) neuroprotective signaling pathway in both rod and cone photoreceptor cells, which is activated through protein–protein interaction. Our previous studies were performed with either retina or isolated rod or cone outer segment preparations and the expression of IR signaling proteins were examined. The isolation of outer segments with large portions of the attached inner segments is a technical challenge. Optiprep? density gradient medium has been used to isolate the cells and subcellular organelles, Optiprep? is a non‐ionic iodixanol‐based medium with a density of 1.320 g/mL. We employed this method to examine the expression of IR and its signaling proteins, and activation of one of the downstream effectors of the IR in isolated photoreceptor cells. Identification of the signaling complexes will be helpful for therapeutic targeting in disease conditions.     

Temporal orientation: circadian clocks in animals and humans

By evolutionary adaptation to the regular day-night changes in environmental conditions, most organisms have acquired a temporal programme which matches the 24-h day. It rests on periodic processes which have the characteristics of self-sustaining oscillations, and which, in constant conditions, free-run with periods slightly deviating from 24 h. When entrained to 24 h, these circadian rhythms can be used by the organism as a clock for temporal orientation, e.g. in the occupation of one of the temporal niches provided by the environment or in the coordination of activities among individuals and species. The circadian clock also provides the basis for using the sun as a compass in spatial orientation, and for the recognition of the time of day as exemplified by the time sense in honey bees. Within the human organism, almost every function is modulated in a circadian fashion. Usually, all rhythms keep a distinct phase-relationship t to each other, providing a high degree of temporal order within the organism. When living in an isolation unit without time cues, most subjects develop free-running rhythms with periods close to 25 h in all functions. Sometimes, however, the sleep-wake cycle is lengthened to 30 h and more, or shortened to less than 22 h. In those instances, other rhythms such as that of body temperature become uncoupled from the sleep-wake cycle and continue to free-run with a period of about 25 h. During such states of ‘internal desynchronization’, subjects can be awake continuously for about 32 h, and sleep without interruption for 16 h. Nevertheless, they experience their ‘days’ as equal to 24 h. This is due to a profound change in time estimation: the intervals of 1-h estimates made by the subject are positively correlated with the duration of wakefulness. In contrast, short-time estimates (in the range of seconds) remain unaffected by desynchronization, indicating that short- and long-time estimates are based on different mechanisms.     

A non‐canonical role of the p97 complex in RIG‐I antiviral signaling

RIG‐I is a well‐studied sensor of viral RNA that plays a key role in innate immunity. p97 regulates a variety of cellular events such as protein quality control, membrane reassembly, DNA repair, and the cell cycle. Here, we report a new role for p97 with Npl4‐Ufd1 as its cofactor in reducing antiviral innate immune responses by facilitating proteasomal degradation of RIG‐I. The p97 complex is able to directly bind both non‐ubiquitinated RIG‐I and the E3 ligase RNF125, promoting K48‐linked ubiquitination of RIG‐I at residue K181. Viral infection significantly strengthens the interaction between RIG‐I and the p97 complex by a conformational change of RIG‐I that exposes the CARDs and through K63‐linked ubiquitination of these CARDs. Disruption of the p97 complex enhances RIG‐I antiviral signaling. Consistently, administration of compounds targeting p97 ATPase activity was shown to inhibit viral replication and protect mice from vesicular stomatitis virus (VSV) infection. Overall, our study uncovered a previously unrecognized role for the p97 complex in protein ubiquitination and revealed the p97 complex as a potential drug target in antiviral therapy.