Modulating the Clock Because of the close association of the circadian clock with a wide range of physiological processes, identification of clock-modulating small molecules may prove useful for the treatment of circadian-related disorders, which include circadian sleep disorders, cardiovascular disease, cancer, and metabolic disease. Hirota et al. (p. 1094 , published online 12 July) screened for chemical compounds that affected the period of the circadian clock in a human osteosarcoma cell line. A carbazole derivative named KL001 appeared to act by inhibiting proteolytic degradation of the cryptochrome proteins, which in turn caused a lengthening of the circadian period. KL001 also inhibited glucagon-induced gluconeogenesis in primary cultures of mouse hepatocytes.
We developed an enhanced green-emitting luciferase (ELuc) to be used as a bioluminescence imaging (BLI) probe. ELuc exhibits a light signal in mammalian cells that is over 10-fold stronger than that of the firefly luciferase (FLuc), which is the most widely used luciferase reporter gene. We showed that ELuc produces a strong light signal in primary cells and tissues and that it enables the visualization of gene expression with high temporal resolution at the single-cell level. Moreover, we successfully imaged the nucleocytoplasmic shuttling of importin α by fusing ELuc at the intracellular level. These results demonstrate that the use of ELuc allows a BLI spatiotemporal resolution far greater than that provided by FLuc.
Summary Background Circadian neural circuits generate near 24 hr physiological rhythms that can be entrained by light to coordinate animal physiology with daily solar cycles. To examine how a circadian circuit reorganizes its activity in response to light, we imaged period (per) clock gene cycling for up to 6 days at single neuron resolution in whole brain explant cultures prepared from per-luciferase transgenic flies. We compared cultures subjected to a phase-advancing light pulse (LP) to cultures maintained in darkness (DD). Results In DD, individual neuronal oscillators in all circadian subgroups are initially well synchronized, then show monotonic decrease in oscillator rhythm amplitude and synchrony with time. The s-LNvs and LNds exhibit this decrease at a slower relative rate. In contrast, the LP evokes a rapid loss of oscillator synchrony between and within most circadian neuronal subgroups followed by gradual phase retuning of whole circuit oscillator synchrony. The LNds maintain high rhythmic amplitude and synchrony following the LP along with the most rapid coherent phase advance. Immunocytochemical analysis of PER show these dynamics in DD and LP are recapitulated in vivo. Anatomically distinct circadian neuronal subgroups vary in their response to the LP, showing differences in the degree and kinetics of their loss, recovery and/or strengthening of synchrony and rhythmicity. Conclusions Transient desynchrony appears to be an integral feature of light response of the Drosophila multicellular circadian clock. Individual oscillators in different neuronal subgroups of the circadian circuit show distinct kinetic signatures of light response and phase retuning.
Histone modification is important for maintaining chromatin structure and function. Recently, histone acetylation has been shown to have a critical regulatory role in both transcription and DNA repair. We report here that expression of histone acetyltransferase (HAT) genes is associated with cisplatin resistance. We found that Tip60 is overexpressed in cisplatin-resistant cells. The expression of two other HAT genes, HAT1 and MYST1, did not differ between drug-sensitive and -resistant cells. Knockdown of Tip60 expression rendered cells sensitive to cisplatin but not to oxaliplatin, vincristine, and etoposide. Tip60 expression is significantly correlated with cisplatin sensitivity in human lung cancer cell lines. Interestingly, the promoter region of the Tip60 gene contains several E boxes, and its expression was regulated by the E-box binding circadian transcription factor Clock but not by other E-box binding transcription factors such as c-Myc, Twist, and USF1. Hyperacetylation of H3K14 and H4K16 was found in cisplatin-resistant cells. The microarray study reveals that several genes for DNA repair are down-regulated by the knockdown of Tip60 expression. Our data show that HAT gene expression is required for cisplatin resistance and suggest that Clock and Tip60 regulate not only transcription, but also DNA repair, through periodic histone acetylation.Our research has focused on factors affecting cellular sensitivity of solid tumors to anticancer agents and investigation of promising molecular targets for cancer treatment (1, 2). Among many drugs, cis-diamminechloroplatinum (II) (cisplatin) plays a crucial role in the treatment of various solid tumors (3, 4). Cisplatin has been shown to form a cross-link between adjacent purines in genomic DNA and can cause DNA-damaging signals to induce apoptosis (1, 2). Cisplatin treatment also induces oxidative and endoplasmic reticulum stresses (5). Thus, the nature of cellular sensitivity to cisplatin is highly complex.The development of cisplatin resistance is a major clinical limitation in cancer chemotherapy. Cisplatin resistance is influenced by many factors which affect intracellular drug accumulation (6 -8), increased activity of intracellular thiol production (9, 10), and DNA repair (11, 12). However, little is known about the molecular mechanisms involved in drug resistance. Cellular factors involved in transcription contribute to the induction of apoptosis or transient or acquired resistance. We have tried to identify the cisplatin-inducible transcription factors and transcription-related factors that are highly expressed in drug-resistant cells (1, 2, 13). We have previously shown that expression of activating transcription factor 4 (ATF4) 2 is inducible by cisplatin treatment and is high in cisplatin-resistant cells (14). The cellular level of ATF4 expression correlates with cisplatin sensitivity in human lung cancer cell lines. DNA microarray analysis has revealed that ATF4 regulates genes involved in glutathione biosynthesis and conjugation (15). Interestingly, ...
Circadian rhythms of mammalian physiology and behavior are coordinated by the suprachiasmatic nucleus (SCN) in the hypothalamus. Within SCN neurons, various aspects of cell physiology exhibit circadian oscillations, including circadian clock gene expression, levels of intracellular Ca2+ ([Ca2+]i), and neuronal firing rate. [Ca2+]i oscillates in SCN neurons even in the absence of neuronal firing. To determine the causal relationship between circadian clock gene expression and [Ca2+]i rhythms in the SCN, as well as the SCN neuronal network dependence of [Ca2+]i rhythms, we introduced GCaMP3, a genetically encoded fluorescent Ca2+ indicator, into SCN neurons from PER2::LUC knock-in reporter mice. Then, PER2 and [Ca2+]i were imaged in SCN dispersed and organotypic slice cultures. In dispersed cells, PER2 and [Ca2+]i both exhibited cell autonomous circadian rhythms, but [Ca2+]i rhythms were typically weaker than PER2 rhythms. This result matches the predictions of a detailed mathematical model in which clock gene rhythms drive [Ca2+]i rhythms. As predicted by the model, PER2 and [Ca2+]i rhythms were both stronger in SCN slices than in dispersed cells and were weakened by blocking neuronal firing in slices but not in dispersed cells. The phase relationship between [Ca2+]i and PER2 rhythms was more variable in cells within slices than in dispersed cells. Both PER2 and [Ca2+]i rhythms were abolished in SCN cells deficient in the essential clock gene Bmal1. These results suggest that the circadian rhythm of [Ca2+]i in SCN neurons is cell autonomous and dependent on clock gene rhythms, but reinforced and modulated by a synchronized SCN neuronal network.
Successful pluripotent stem cell differentiation methods have been developed for several endoderm-derived cells, including hepatocytes, β-cells and intestinal cells. However, stomach lineage commitment from pluripotent stem cells has remained a challenge, and only antrum specification has been demonstrated. We established a method for stomach differentiation from embryonic stem cells by inducing mesenchymal Barx1, an essential gene for in vivo stomach specification from gut endoderm. Barx1-inducing culture conditions generated stomach primordium-like spheroids, which differentiated into mature stomach tissue cells in both the corpus and antrum by three-dimensional culture. This embryonic stem cell-derived stomach tissue (e-ST) shared a similar gene expression profile with adult stomach, and secreted pepsinogen as well as gastric acid. Furthermore, TGFA overexpression in e-ST caused hypertrophic mucus and gastric anacidity, which mimicked Ménétrier disease in vitro. Thus, in vitro stomach tissue derived from pluripotent stem cells mimics in vivo development and can be used for stomach disease models.
In mammals, circadian rhythms are driven by a pacemaker located in the suprachiasmatic nuclei (SCN) of the hypothalamus. The pacemaker is composed of an ensemble of multiple, single-cell oscillators in the SCN. We measured arginine-vasopressin (AVP) release in organotypic SCN slices. The SCN slice culture showed circadian oscillation of AVP release with a period length (+/- SEM) of 23.84 +/- 00.03 h. This period is very similar to the one we previously reported in dispersed SCN cultures and is also close to that of behavioural rhythms. When the ventral part was removed by a surgical cut across the slice in the horizontal plane, however, the period became shorter (23.22 +/- 00.08 h). On the other hand, the removal of the dorsal part did not affect period length. These results suggest that the oscillators in ventral and dorsal cells contribute differently to period length and that the dorsal oscillators are entrained by the ventral ones to form a single integrated oscillator.
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