Molecular basis of spectral tuning in the newt short wavelength sensitive visual pigment

Previously we reported the sequence of the member of the short wavelength sensitive 2 (SWS2) family of vertebrate visual pigments from the retina of the Japanese common newt, Cynops pyrrhogaster[Takahashi, Y. et al. (2001) FEBS Lett. 501, 151-155]. Now we have expressed the apopigment and regenerated it with A1 retinal. Its absorption maximum, 474 nm, is greatly red shifted compared to other known SWS2 pigments (418-455 nm). To determine the amino acid residues that control its spectral tuning, we replaced the residues that were near the chromophore and which differed between the newt and the bullfrog (lambda(max) = 430 nm) wild-type SWS2 pigments: Pro91Ser, Ser94Ala, Ile122Met, Cys127Ser, Ser211Cys, Tyr261Phe, and Ala292Ser. Each of these site-directed mutants led to blue shifts of the newt pigment with five of them causing substantial shifts; their sum was about equal to the difference between the absorption maximum of the bullfrog and newt pigments, 44 nm. The 32 nm shift of the absorption maximum of the multiple seven-residue mutant to 442 nm is fairly close to that of the wild-type bullfrog pigment. Thus, the seven amino acid residues that we replaced are the major cause of the red shift of the newt SWS2 pigment's spectrum. Two of the residues, 91 and 94, have not previously been identified as wavelength regulating sites in visual pigments. One of these, 91, probably regulates color via a new mechanism: altering of a hydrogen bonding network that is connected via a water to the chromophore, in this case its counterion, Glu113.     

Minimally modified LDL is an oxidized LDL enriched with oxidized phosphatidylcholines

The oxidative modification of low-density lipoprotein (LDL) is involved in atherogenesis. Among a variety of modified LDLs mentioned in the literature, so-called minimally modified LDL (MM-LDL) was reported to have pro-atherogenic properties despite minimal changes in its oxidative measures. After treatment of LDL with 1 micro M FeSO(4) at 4 degrees C for 96 h, the resulting MM-LDL showed a slight increase in thiobarbituric acid-reactive substances (TBARS) and little association with macrophages. On the other hand, heavily oxidized LDL, which was prepared by copper-induced oxidation of LDL at 37 degrees C, showed a sharp increase in TBARS and strong association with macrophages. By introducing a fluorometric procedure to detect aldehyde-containing phosphatidylcholines (aldehyde-PCs), we examined the amounts of aldehyde-PCs in modified LDL preparations. Aldehyde-PCs increased to 23.4 pmol/ microg protein in MM-LDL, which was more than four-fold higher than in the heavily oxidized LDL. We conclude that MM-LDL is a unique type of oxidized LDL enriched with aldehyde-PCs.     

Site-directed mutagenesis of benzalacetone synthase. The role of the Phe215 in plant type III polyketide synthases

Benzalacetone synthase (BAS) and chalcone synthase (CHS) are plant-specific type III polyketide synthases (PKSs) that share approximately 70% amino acid sequence identity. BAS catalyzes a one-step decarboxylative condensation of 4-coumaroyl-CoA with malonyl-CoA to produce a diketide benzalacetone, whereas CHS performs sequential condensations with three malonyl-CoA to generate a tetraketide chalcone. A homology model suggested that BAS has the same overall fold as CHS with cavity volume almost as large as that of CHS. One of the most characteristic features is that Rheum palmatum BAS lacks active site Phe-215; the residues 214LF conserved in type III PKSs are uniquely replaced by IL. Our observation that the BAS I214L/L215F mutant exhibited chalcone-forming activity in a pH-dependent manner supported a hypothesis that the absence of Phe-215 in BAS accounts for the interruption of the polyketide chain elongation at the diketide stage. On the other hand, Phe-215 mutants of Scutellaria baicalensis CHS (L214I/F215L, F215W, F215Y, F215S, F215A, F215H, and F215C) afforded increased levels of truncated products; however, none of them generated benzalacetone. These results confirmed the critical role of Phe-215 in the polyketide formation reactions and provided structural basis for understanding the structure-function relationship of the plant type III PKSs.     

Enhancement of oxidative damage to cultured cells and Caenorhabditis elegans by mitochondrial electron transport inhibitors

The mechanisms that lead to mitochondrial damage under oxidative stress conditions were examined in primary and cultured cells as well as in the nematode Caenorhabditis elegans (C. elegans) treated simultaneously with electron transport inhibitors and oxygen gas. Oxygen loading enhanced the damage of PC 12 cells by thenoyltrifluoroacetone (TTFA, a complex II inhibitor), but did not by rotenone (a complex I inhibitor), antimycin (a complex III inhibitor), and sodium azide (a complex IV inhibitor). In primary hepatocytes, the enhancement was observed with the addition of sodium azide and rotenone, but not by TTFA or antimycin. In the nematode, only rotenone and TTFA enhanced the sensitivity under hyperoxia. These results demonstrate that highly specific inhibitors of electron transport can induce oxygen hypersensitivity in cell levels such as PC 12 cells and primary hepatocytes, and animal level of C. elegans. In addition the cell damage is different dependent on cell type and organism.     

High-cut characteristics of the baroreflex neural arc preserve baroreflex gain against pulsatile pressure

A transfer function from baroreceptor pressure input to sympathetic nerve activity (SNA) shows derivative characteristics in the frequency range below 0.8 Hz in rabbits. These derivative characteristics contribute to a quick and stable arterial pressure (AP) regulation. However, if the derivative characteristics hold up to heart rate frequency, the pulsatile pressure input will yield a markedly augmented SNA signal. Such a signal would saturate the baroreflex signal transduction, thereby disabling the baroreflex regulation of AP. We hypothesized that the transfer gain at heart rate frequency would be much smaller than that predicted from extrapolating the derivative characteristics. In anesthetized rabbits (n = 6), we estimated the neural arc transfer function in the frequency range up to 10 Hz. The transfer gain was lost at a rate of -20 dB/decade when the input frequency exceeded 0.8 Hz. A numerical simulation indicated that the high-cut characteristics above 0.8 Hz were effective to attenuate the pulsatile signal and preserve the open-loop gain when the baroreflex dynamic range was finite.     

Distribution of interstitial telomere-like repeats and their adjacent sequences in a dioecious plant, <Emphasis Type="Italic">Silene latifolia</Emphasis>

The dioecious plant Silene latifolia has large, heteromorphic X and Y sex chromosomes that are thought to be derived from rearrangements of autosomes. To reveal the origin of the sex chromosomes in S. latifolia, we isolated and characterized telomere-homologous sequences from intra-chromosomal regions (interstitial telomere-like repeats; ITRs) and ITR-adjacent sequences (IASs). Nine genomic DNA fragments with degenerate 84- to 175-bp ITRs were isolated from a genomic library and total genome of male plants. Comparing the nucleotide sequences, the IASs of the nine ITRs were classified into seven elements (IAS-a, IAS-b, IAS-c, IAS-d, IAS-e, IAS-f, and IAS-g) by sequence similarity. The ITRs were grouped into two classes (class-I and -II ITRs) according to the classification of IASs. The class-I ITRs were sub-grouped into three subclasses (subclasses-IA, -IB, and -IC ITRs) based on the arrangement of IAS elements. By contrast, the class-II ITR was located between two different IASs (IAS-f and IAS-g). Genomic Southern analyses showed that both the male and female genomes contained six (IAS-f) to 153 (IAS-d) copies of each IAS per haploid genome. Fluorescence in situ hybridization analyses showed that one IAS element, IAS-d, was distributed in the interstitial and proximal regions of the sex chromosomes of S. latifolia. The distribution of IAS-d is important evidence for past telomere-mediated chromosome rearrangements during the evolution of the sex chromosomes of S. latifolia.     

Susceptibility to T cell-mediated injury in immune complex disease is linked to local activation of renin-angiotensin system: the role of NF-AT pathway

FcR provides a critical link between ligands and effector cells in immune complex diseases. Emerging evidence reveals that angiotensin (Ang)II exerts a wide variety of cellular effects and contributes to the pathogenesis of inflammatory diseases. In anti-glomerular basement membrane Ab-induced glomerulonephritis (GN), we have previously noted that FcR-deficient mice (gamma(-/-)) surviving from lethal initial damage still developed mesangial proliferative GN, which was drastically prevented by an AngII type 1 receptor (AT1) blocker. We further examined the mechanisms by which renin-Ang system (RAS) participates in this immune disease. Using bone marrow chimeras between gamma(-/-) and AT1(-/-) mice, we found that glomerular injury in gamma(-/-) mice was associated with CD4(+) T cell infiltration depending on renal AT1-stimulation. Based on findings in cutaneous delayed-type hypersensitivity, we showed that AngII-activated renal resident cells are responsible for the recruitment of effector T cells. We next examined the chemotactic activity of AngII-stimulated mesangial cells, as potential mechanisms coupling RAS and cellular immunity. Chemotactic activity for T cells and Th1-associated chemokine (IFN-gamma-inducible protein-10 and macrophage-inflammatory protein 1alpha) expression was markedly reduced in mesangial cells from AT1(-/-) mice. Moreover, this activity was mainly through calcineurin-dependent NF-AT. Although IFN-gamma-inducible protein-10 was NF-kappaB-dependent, macrophage-inflammatory protein 1alpha was dominantly regulated by NF-AT. Furthermore, AT1-dependent NF-AT activation was observed in injured glomeruli by Southwestern histochemistry. In conclusion, our data indicate that local RAS activation, partly via the local NF-AT pathway, enhances the susceptibility to T cell-mediated injury in anti-glomerular basement membrane Ab-induced GN. This novel mechanism affords a rationale for the use of drugs interfering with RAS in immune renal diseases.     

Changes in flower coloration and sepal anthocyanins of Cyanic delphinium cultivars during flowering

The changes in flower color related to sepal pigmentation of cyanic Delphinium cultivars were investigated during anthesis. The sepal hues of the purple and blue flowered varieties observed on the initial day of unfurling had changed with a decrease in hue angle three days after anthesis. In both the purple and blue cultivars, violdelphin (3) was the major component on day one of anthesis, and the chromaticity improved with increasing sepal concentrations of violdelphin (3) and cyanodelphin (4) after three days of unfurling. The flower hue was dominated by the constitution of acylated anthocyanins, and the chromaticity was ordered by the sepal concentration. The biosynthesis of cyanodelphin (4) from violdelphin (3) was postulated since an increase in the sepal concentration of cyanodelphin (4) was accompanied by a decrease in violdelphin (3). Acylation of the anthocyanins was initiated by an increase in the respective possible precursors, tulipanin (2) and violdelphin (3), to subsequently synthesize violdelphin (3) and cyanodelphin (4) during flowering.     

Expression of Apc2 during mouse development

APC2 (previously known as APCL), a molecule closely related to the adenomatous polyposis coli (APC) tumor suppressor, can deplete cytoplasmic beta-catenin, like APC itself. Recently, it has been shown that APC2 may regulate the localization of p53 and the microtubule stability and/or extension. Although it has been reported that APC2 mRNA is expressed in human brain, the anatomical and ontogenic expression patterns remain unclear. The purpose of this study was to investigate the distribution of mouse Apc2 during mouse development. In the adult brain, Apc2 is expressed predominantly in neurons and throughout the brain. Northern blot analysis demonstrated a high level of Apc2 expression in embryonic and early postnatal brain. Ontogenic analysis has indicated that Apc2 is expressed in neural tissue, including the peripheral nervous system. During development of cortex, retina and cerebellum, Apc2 is expressed in post-mitotic cells. These findings suggest that Apc2 may contribute to the development of neuronal cells.