Diurnal and Circadian Light-Harvesting Complex and Quinone B-Binding Protein Synthesis in Leaves of Tomato (Lycopersicon esculentum)

In leaves of tomato (Lycopersicon esculentum), the synthesis of a light-harvesting complex (LHC) polypeptide of photosystem II and the quinone B (Q_B)-binding protein varies at different time points during the day. In vivo labeling with [³⁵S]methionine revealed diurnal oscillations of synthesis of these thylakoid membrane proteins. Both proteins are synthesized at elevated levels right after the transition from darkness to light, a maximum is reached around noon, and decreasing levels were measured during the afternoon and night. In addition, in constant darkness both proteins were also synthesized to varied extents at different diurnal time points. Together, these results indicate that the synthesis of a LHC II and the Q_B-binding protein is under the control of the circadian clock. This circadian oscillation of LHC II protein synthesis correlates with the very well documented circadian Lhc a/b mRNA accumulation.     

The effect of heat shock on morphogenesis in barley : coordinated circadian regulation of mRNA levels for light-regulated genes and of the capacity for accumulation of chlorophyll protein complexes

The effect of daily heat-shock treatments on gene expression and morphogenesis of etiolated barley (Hordeum vulgare) was investigated. Heat-shock treatments in the dark induced shortening of the primary leaves and the coleoptiles to the length of those in light-grown plantlets. In addition, the mRNA levels of the light-induced genes that were investigated were raised under these conditions and showed distinct oscillations over a period of at least 3 d. While the mRNA levels for chlorophyll a/b binding protein (LHC II), plastocyanin, and the small subunit of ribulose-1,5-bisphosphate carboxylase had maxima between 8 and 12 pm (12-16h after the last heat-shock treatment), the mRNA levels for thionin oscillated with a phase opposed to that of LHC II. Etiolated barley, the circadian oscillator of which was synchronized by cyclic heatshock treatments, was illuminated for a constant interval at different times of the day; this led to the finding that greening was fastest at the time when the maximal levels of mRNA for LHC II were also observed. Whereas accumulation of chlorophyll a during a 4-h period of illumination oscillated by a factor of 3, chlorophyll b accumulation changed 10- to 15-fold. Similarly, accumulation of LHC II was highest when pigments accumulated maximally. Hence, greening or, in other words, thylakoid membrane assembly is under control of the circadian oscillator.     

Circadian expression of the light-harvesting protein of Photosystem II in etiolated bean leaves following a single red light pulse: Coordination with the capacity of the plant to form chlorophyll and the thylakoid-bound protease

The appearance of the light harvesting II (LHC II) protein in etiolated bean leaves, as monitored by immunodetection in LDS-solubilized leaf protein extracts, is under phytochrome control. A single red light pulse induces accumulation of the protein, in leaves kept in the dark thereafter, which follows circadian oscillations similar to those earlier found for Lhcb mRNA (Tavladoraki et al. (1989) Plant Physiol 90: 665–672). These oscillations are closely followed by oscillations in the capacity of the leaf to form Chlorophyll (Chl) in the light, suggesting that the synthesis of the LHC II protein and its chromophore are in close coordination. Experiments with levulinic acid showed that PChl(ide) resynthesis does not affect the LHC II level nor its oscillations, but new Chl a synthesis affects LHC II stabilization in thylakoids, implicating a proteolytic mechanism. A proteolytic activity against exogenously added LHC II was detected in thylakoids of etiolated bean leaves, which was enhanced by the light pulse. The activity, also under phytochrome control, was found to follow circadian oscillations in verse to those in the stabilization of LHC II protein in thylakoids. Such a proteolytic mechanism therefore, may account for the circadian changes observed in LHC II protein level, being implicated in pigment-protein complex assembly/stabilization during thylakoid biogenesis.Abbreviations Chl chlorophyll - CL continuous light - D dark - FR far-red light - LA levulinic acid - LHC II light-harvesting complex serving Photosystem II - PChl(ide) protochlorophyllide - PCR protochlorophyllide oxidoreductase - R red light     

Daily Oscillation of Fatty Acids and Malondialdehyde in the Dinoflagellate Lingulodinium polyedrum

The levels of the fatty acids, cis eicosahexenoic acid and cis linolenic acid, as well as the extent of lipoperoxidation, measured as malondialdehyde (MDA), were analyzed in the photosynthetic marine dinoflagellate Lingulodinium polyedrum at different times during the light : dark (L : D) cycle. Levels of MDA were twice as high during the day phase than during the night phase. This may be related to the circadian rhythm in photosynthesis as during photosynthetic electron flux, electrons can 'leak' and react with molecular oxygen producing reactive oxygen species (ROS) which in turn react with lipids, proteins, and DNA among other biomolecules. Fatty acid levels were highest during the day phase. Our findings indicate that unsaturated fatty acids are more susceptible to attack and degradation when L. polyedrum is exposed to light and that the cells compensate for this by an increased fatty acid content during the day. Excessive lipoperoxidation during the light phase could result in a higher level of chloroplast or plasma membrane disruption leading to cell death.     

Impaired expression of the mPer2 circadian clock gene in the suprachiasmatic nuclei of aging mice

The expression of circadian clock genes was investigated in the suprachiasmatic nuclei (SCN) of young adult and old laboratory mice. Samples were taken at two time points, which corresponded to the expected maximum (circadian time 7 [CT7]) or minimum (CT21) of mPer mRNA expression. Whereas the young mice had a stable and well-synchronized circadian activity/rest cycle, the rhythms of old animals were less stable and were phase advanced. The expression of mPer1 mRNA and mPer2 mRNA was rhythmic in both groups, with peak values at CT7. The levels of mClock and mCry1 mRNA were not different depending on the time of day and did not vary with age. In contrast, an age-dependent difference was found in the case of mPer2 (but not mPer1) mRNA expression, with the maximum at CT7 significantly lower in old mice. The decreased expression of mPer2 may be relevant for the observed differences in the overt activity rhythm of aged mice. (Chronobiology International, 18(3), 559-565, 2001)     

Expression pattern of mouse sFRP-1 and mWnt-8 gene during heart morphogenesis

The Wnt genes encode a large family of secreted proteins that play a key role in embryonic development and tissue differentiation in many species (Rijsewijk et al., 1987 and Nusse and Varmus, 1992). Genetic and biochemical studies have suggested that the frizzled proteins are cell surface receptors for Wnts (Vinson et al., 1989, Chan et al., 1992, Bhanot et al., 1996 and Wang et al., 1996). In parallel, a number of secreted frizzled-like proteins with a conserved N-terminal frizzled motif have been identified (Finch et al., 1997, Melkonyan et al., 1997 and Rattner et al., 1997). One of these proteins, FrzA, the bovine counterpart of the murine sFRP-1 (93% identity) is involved in vascular cell growth control, binds Wg in vitro and antagonizes Xwnt-8 and hWnt-2 signaling in Xenopus embryos (Xu et al., 1998 and Duplàa et al., 1999). In this study, we report that sFRP-1 is expressed in the heart and in the visceral yolk sac during mouse development, and that sFRP-1 and mWnt-8 display overlapping expression patterns during heart morphogenesis. From 8.5 to 12.5 d.p.c., sFRP-1 is expressed in cardiomyocytes together with mWnt-8 but neither in the pericardium nor in the endocardium; at 17.5 d.p.c., they are no longer present in the heart. In mouse adult tissues, while sFRP-1 is highly detected in the aortic endothelium and media and in cardiomyocytes, mWnt-8 is not detected in these areas. Immunoprecipitation experiments demonstrates that FrzA binds to mWnt-8 in cell culture experiments.     

The function of circadian RNA-binding proteins and their cis-acting elements in microalgae

An endogenous clock regulates the temporal expression of genes/mRNAs that are involved in the circadian output pathway. In the bioluminescent dinoflagellate Gonyaulax polyedra circadian expression of the luciferin-binding protein (LBP) is controlled at the translational level. Thereby, a clock-controlled RNA-binding protein, called circadian controlled translational regulator (CCTR), interacts specifically with an UG-repeat, which is situated in the lbp 3^' UTR. Its binding activity correlates negatively with the amount of LBP during a circadian cycle. In the green alga Chlamydomonas reinhardtii, a clock-controlled RNA-binding protein (CHLAMY 1) was identified, which represents an analog of the CCTR from the phylogenetically diverse alga G. polyedra. CHLAMY 1 binds specifically to the 3^' UTRs of several mRNAs and recognizes them all via a common cis-acting element, composed of at least seven UG-repeats. The binding strength of CHLAMY 1 is strongest to mRNAs, whose products are key components of nitrogen metabolism resulting in arginine biosynthesis as well as of CO₂ metabolism. Since temporal activities of processes involved in nitrogen metabolism have an opposite phase than CHLAMY 1 binding activity, the protein might repress the translation of the cognate mRNAs.     

Interaction of MAR-sequences with nuclear matrix proteins.

The recent discovery of DNA sequences responsible for the specific attachment of chromosomal DNA to the nuclear skeleton (MARs/SARs) was an important step towards our understanding of the functional and structural organization of eukaryotic chromatin [Mirkovitch et al.: Cell 44:273-282, 1984; Cockerill and Garrard: Cell 44:273-282, 1986]. A most important question, however, remains the nature of the matrix proteins involved in the specific binding of the MARs. It has been shown that topoisomerase II and histone H1 were capable of a specific interaction with SARs by the formation of precipitable complexes [Adachi et al.: EMBO J8:3997-4006, 1989; Izaurralde et al.: J Mol Biol 210:573-585, 1989]. Here, applying a different approach, we were able to "visualize" some of the skeletal proteins recognizing and specifically binding MAR-sequences. It is shown that the major matrix proteins are practically the same in both salt- and LIS-extracted matrices. However, the relative MAR-binding activity of the individual protein components may be different, depending on the method of matrix preparation. The immunological approach applied here allowed us to identify some of the individual MAR-binding matrix proteins. Histone H1 and nuclear actin are shown to be not only important components of the matrix, but to be involved in a highly efficient interaction with MAR-sequences as well. Evidence is presented that proteins recognized by the anti-HMG antibodies also participate in MAR-interactions.     

棉铃虫生物钟基因HeDbt的克隆和表达模式分析

【目的】克隆并分析棉铃虫Helicoverpa armigera生物钟基因Double-time (Dbt),明确该基因的昼夜表达模式,探讨其表达水平的影响因子,为研究夜蛾科昆虫复眼中生物钟基因的作用机制奠定基础,为理解外周组织中生物钟基因功能提供参考。【方法】采用RT-PCR和RACE技术从2日龄棉铃虫雌成虫复眼中克隆生物钟基因Dbt,并利用在线网站和软件进行生物信息学分析。采用qPCR技术检测棉铃虫雌、雄成虫不同组织(头、脑、复眼、触角、胸、腹、足和翅)中Dbt的表达水平;检测光周期14L∶10D和持续黑暗(DD)下雌、雄成虫头和复眼中Dbt的昼夜表达模式;在暗期用棉铃虫敏感波段光(UV、蓝光和绿光)照射2日龄成虫6 h,检测复眼中Dbt表达水平的变化;在暗期进行雌、雄成虫交配,检测交配结束及3 h后复眼中Dbt表达水平的变化。【结果】成功克隆到棉铃虫生物钟基因Dbt的cDNA序列,命名为HeDbt(GenBank登录号: KM233159),开放阅读框长1 026 bp,编码314个氨基酸组成的多肽。HeDbt理论推测分子量为39.79 kD,等电点(pI)为9.55,不具有跨膜拓扑结构,包含典型的昆虫DBT蛋白保守区域,其与甜菜夜蛾Spodoptera exigua和柞蚕Antheraea pernyi DBT的同源性较高, 氨基酸序列一致性分别为99%和97%。qPCR结果表明,HeDbt在成虫各组织中均有表达,在头、脑和复眼中表达水平较低,在胸和腹中表达水平较高;在14L∶10D和DD下,头和复眼中HeDbt未呈现明显的昼夜表达节律。暗期光照和交配后,复眼中HeDbt的表达均显著下调,但雌、雄成虫间HeDbt表达水平整体相似。【结论】成功克隆得到棉铃虫生物钟基因HeDbt,其在棉铃虫成虫头和复眼中表达水平较低,且不具有昼夜规律性,但复眼中Dbt的表达受到光照和交配的影响。本研究为进一步探索夜蛾外周组织生物钟基因功能奠定了基础。     

Exploring the signaling pathway of circadian bioluminescence

Bioluminescence in the unicellular dinoflagellate Gonyaulax polyedra represents an excellent model for studying a circadian controlled process at the biochemical and molecular levels. There are three key components involved in the bioluminescence reaction: the enzyme, luciferase, its substrate, luciferin, and a luciferin-binding protein (LBP), which sequesters the substrate at p^H 7.5 and thus prevents it from reacting with the enzyme. All components are tightly packed together in organdies, designated scintillons. The entire bioluminescent system is under circadian control with maximum amounts in the night. For both proteins circadian control is exerted at the translational level. In case of Ibp mRNA a small interval in its 3'untranslated region serves as a cis -acting element to which a trans -factor binds in a circadian manner. The binding activity of this factor decreases at the beginning of the night phase, when synthesis of LBP starts, and it increases al the end of the night, when synthesis of LBP stops indicating that it functions as a clock-controlled represser.     

THE CIRCADIAN RHYTHM OF BIOLUMINESCENCE IN PYROCYSTIS IS NOT DUE TO DIFFERENCES IN THE AMOUNT OF LUCIFERASE: A COMPARATIVE STUDY OF THREE BIOLUMINESCENT MARINE DINOFLAGELLATES

The biochemistry and circadian regulation of luminescence in two Pyrocystis species, P. lunula Hulburt and P. noctiluca Murray et Haeckel, were compared with a well-studied species, Gonyaulax polyedra Stein. All exhibit circadian rhythms and all have similar luciferins and luciferases. However, the Pyrocystis species lack a second protein involved in the reaction in Gonyaulax , the luciferin (substrate) binding protein, which sequesters the luciferin at the cytoplasmic pH and releases it upon acidification, thus controlling the characteristic flashing, which is similar in the three species. More striking is the difference in the circadian regulation of luminescence, which in Gonyaulax involves the daily synthesis and destruction of the two proteins, along with the luminous organelles (scintillons) from which light is emitted, and which are present in all species. In the Pyrocystis species, the amount of luciferase is the same in extracts made during the day and night phases; its circadian regulation in vivo may be attributed to a change in its localization from day to night phase.