A blue light (BL) receptor was discovered in stramenopile algae
Background: Aureochromes in stramenopiles are thought to function as light-regulated transcription factors, although the molecular mechanism is unknown. Results: Monomeric AUREO1 is present in reduced conditions and undergoes dimerization upon illumination. Conclusion: Blue light-induced dimerization enhances the affinity for the target sequence. Significance: AUREO1 is useful for understanding the blue light responses of stramenopiles, and for optogenetics and biophysical analyses.
Aureochrome-1 (AUREO1) is a blue light (BL) receptor that mediates the branching response in the stramenopile alga, Vaucheria frigida. AUREO1 harbors a basic leucine zipper (bZIP) domain at the N-terminus and a light-oxygen-voltage-sensing (LOV) domain within the C-terminal region, and has been suggested to function as a light-regulated transcription factor. To understand the molecular mechanism of AUREO1, we have prepared three recombinant proteins: a full-length AUREO1 (FL), an N-terminal truncated construct containing bZIP and LOV (ZL) and a LOV-only (LOV) construct. The constructs showed the same absorption and fluorescent spectra in the dark state and underwent the characteristic cyclic reaction as previously observed in LOV domains upon BL excitation. FL and ZL bound to DNA in a sequence-specific manner. BL appeared to induce a shift of the α-helical structure of the LOV domain to a β-sheet structure, but did not alter the hydrodynamic radius (R(H)) of this domain. ZL formed a dimer possibly through disulfide linkages in the bZIP and the linker region between bZIP and LOV. BL induced an approximately 5% increase in the R(H) of ZL, although its secondary structure was unchanged. These results support a schema where BL-induced changes in the LOV domain may cause conformational changes in the bZIP and/or the linker of a dimeric ZL molecule. Since a 5% increase of the R(H) was also observed with the FL construct, BL may induce global conformational changes similar to those observed for ZL, and formation of the FL dimer may facilitate DNA binding.
Aureochrome is a recently discovered blue light photosensor that controls a light-dependent morphology change. As a photosensor, it has a unique DNA binding domain (bZIP). Although the biological functions of aureochrome have been revealed, the fundamental photochemistry of this protein has not been elucidated. The photochemical reaction dynamics of the LOV (light, oxygen, or voltage) domain of aureochrome-1 (AUREO1-LOV) and the LOV domain with the bZIP domain (AUREO1-ZL) were studied by employing the transient-grating (TG) technique, using size-exclusion chromatography to verify results. For both samples, adduct formation takes place with a time constant of 2.8 μs. Although significant diffusion changes were observed for both AUREO1-LOV and AUREO1-ZL after adduct formation, the origins of these changes were significantly different. The TG signal of AUREO1-LOV was strongly concentration-dependent. From analysis of the signal, it was concluded that AUREO1-LOV exists in equilibrium between the monomer and dimer, and dimerization of the monomer is the main reaction, i.e., irradiation with blue light enhances the strength of the interdomain interaction. On the other hand, the reaction of AUREO1-ZL is independent of concentration, suggesting that an intraprotein conformational change occurs in the bZIP domain with a time constant of 160 ms. These results revealed the different reactions and roles of the two domains; the LOV domain acts as a photosensor, leading to a subsequent conformational change in the bZIP domain, which should change its ability to bind to DNA. A model is proposed that demonstrates how aureochrome uses blue light to control its affinity for DNA.
The new type blue light (BL) receptor aureochrome (AUREO) was recently discovered in a stramenopile alga, Vaucheria (Takahashi et al. Proc Natl Acad Sci USA 104(49):19625-19630, 2007). AUREO has a bZIP (basic region/leucine zipper) and BL-sensing light-oxygen-voltage (LOV) domain and functions as a BL-activated transcription factor. It mediates BL-induced branching and regulates the development of the sex organ in V. frigida. Although AUREO sequences have previously been found in Fucus and some diatoms, here we report that AUREO orthologs are commonly conserved in photosynthetic stramenopiles. Five AUREO orthologs were isolated from three stramenopile genera (Fucus, Ochromonas, and Chattonella). By BLAST search, several AUREO sequences were also detected in genomes in Aureococcus anophagefferens (Pelagophyceae). However, AUREO was not found in heterotrophic stramenopiles or in closely related phyla, such as haptophytes and cryptophytes, or in green plants. Stramenopiles do not possess phototropin, the well-known BL receptor for phototropism of green plants. From comparative analysis of LOV domains, together with kinship analysis of AUREO bZIP domains, AUREO can be regarded as the BL receptor specific to phototrophic stramenopiles. The evolution of AUREO and the phylogeny of LOV domains in stramenopiles and green plants are discussed.
The increase in the proportion of elderly people in the population is one of the most remarkable sociodemographic phenomena of the twenty-first century. The number of patients with diabetes is also increasing worldwide with this demographic change. Given these facts, consideration of the problems the general elderly population is facing in the management of diabetes is essential. In this review article, we focus on sarcopenia, which is the decrease in lower extremity muscle mass and muscle strength accompanying aging, describe the relationship between sarcopenia and diabetes, and highlight the specific factors through which diabetes contributes to loss of muscle strength. The quantitative methods for evaluating lower extremity muscle strength will also be described. These methods hold the key to assessing the effectiveness of exercise therapy and optimizing the assessment of the degree of autonomy in the activities of daily living. Exercise is one of the basic treatments for type 2 diabetes and may also prevent and improve sarcopenia. This review discusses the aspects common to the two health conditions and elucidates the effectiveness and necessity of exercise as a preventive measure against diabetes among the elderly.
Because the secondary plastids of the Euglenophyta and Chlorarachniophyta are very similar to green plant plastids in their pigment composition, it is generally considered that ancestral green algae were engulfed by other eukaryotic host cells to become the plastids of these two algal divisions. Recent molecular phylogenetic studies have attempted to resolve the phylogenetic positions of these plastids; however, almost all of the studies analyzed only plastid‐encoded genes. This limitation may affect the results of comparisons between genes from primary and secondary plastids, because genes in endosymbionts have a higher mutation rate than the genes of their host cells. Thus, the phylogeny of these secondary plastids must be elucidated using other molecular markers. Here, we compared the plastid‐targeting, nuclear‐encoded, oxygen‐evolving enhancer (psbO) genes from various green plants, the Euglenophyta and Chlorarachniophyta. A phylogenetic analysis based on the PsbO amino acid sequences indicated that the chlorarachniophyte plastids are positioned within the Chlorophyta (including Ulvophyceae, Chlorophyceae, and Prasinophyceae, but excluding Mesostigma). In contrast, plastids of the Euglenophyta and Mesostigma are positioned outside the Chlorophyta and Streptophyta. The relationship of these three phylogenetic groups was consistent with the grouping of the primary structures of the thylakoid‐targeting domain and its adjacent amino acids in the PsbO N‐terminal sequences. Furthermore, the serine‐X‐alanine (SXA) motif of PsbO was exactly the same in the Chlorarachniophyta and the prasinophycean Tetraselmis. Therefore, the chlorarachniophyte secondary plastids likely evolved from the ancestral Tetraselmis‐like alga within the Chlorophyta, whereas the Euglenophyte plastids may have originated from the unknown basal lineage of green plants.
When a narrow region of the fresh water coenocytic alga, Vaucheria terrestris sensu Götz is irradiated with moderately intense blue light, a branch is induced from the center of the irradiated region after 4-5 h. Movement of organelles and microtubule bundles during the photocytomorphogenetic response were investigated. Chloroplasts in the cortical layer immediately started to accumulate in the blue light-irradiated region and their accumulation almost completely finished 30-40 min after the onset of light when the nuclei residing in endoplasm started to accumulate. Accumulation of nuclei was synchronized with disorientation and shortening of microtubule bundles, which originally run parallel to the cell axis. Not only amiprophos-methyl, a potent microtubule-decomposing reagent, but also cytochalasin A strongly inhibited the branch induction. Amiprophos-methyl completely and cytochalasin A mostly destroyed microtubules and completely inhibited nuclear accumulation, but both drugs allowed the accumulation of chloroplasts in the cortical layer of irradiated region. These indicate that the accumulation of nuclei is indispensable for branch induction while the chloroplast accumulation is insufficient by itself for branch induction. The ineffectiveness of cytochalasin A on chloroplast movement brings the conventional view of sliding movement of chloroplast on a long actin cable into question. The morphological and functional relationship between a nucleus and a microtubular bundle are discussed.
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