Tight Coupling between Glucose and Mitochondrial Metabolism in Clonal ��-Cells Is Required for Robust Insulin Secretion

The biochemical mechanisms underlying glucose-stimulated insulin secretion from pancreatic β-cells are not completely understood. To identify metabolic disturbances in β-cells that impair glucose-stimulated insulin secretion, we compared two INS-1-derived clonal β-cell lines, which are glucose-responsive (832/13 cells) or glucose-unresponsive (832/2 cells). To this end, we analyzed a number of parameters in glycolytic and mitochondrial metabolism, including mRNA expression of genes involved in cellular energy metabolism. We found that despite a marked impairment of glucose-stimulated insulin secretion, 832/2 cells exhibited a higher rate of glycolysis. Still, no glucose-induced increases in respiratory rate, ATP production, or respiratory chain complex I, III, and IV activities were seen in the 832/2 cells. Instead, 832/2 cells, which expressed lactate dehydrogenase A, released lactate regardless of ambient glucose concentrations. In contrast, the glucose-responsive 832/13 line lacked lactate dehydrogenase and did not produce lactate. Accordingly, in 832/2 cells mRNA expression of genes for glycolytic enzymes were up-regulated, whereas mitochondria-related genes were down-regulated. This could account for a Warburg-like effect in the 832/2 cell clone, lacking in 832/13 cells as well as primary β-cells. In human islets, mRNA expression of genes such as lactate dehydrogenase A and hexokinase I correlated positively with HbA_1c levels, reflecting perturbed long term glucose homeostasis, whereas that of Slc2a2 (glucose transporter 2) correlated negatively with HbA_1c and thus better metabolic control. We conclude that tight metabolic regulation enhancing mitochondrial metabolism and restricting glycolysis in 832/13 cells is required for clonal β-cells to secrete insulin robustly in response to glucose. Moreover, a similar expression pattern of genes controlling glycolytic and mitochondrial metabolism in clonal β-cells and human islets was observed, suggesting that a similar prioritization of mitochondrial metabolism is required in healthy human β-cells. The 832 β-cell lines may be helpful tools to resolve metabolic perturbations occurring in Type 2 diabetes.     

A report on three live births in women with poor ovarian response following intra-ovarian injection of platelet-rich plasma (PRP)

Molecular Biology Reports - The prevalence of poor response to gonadotropin stimulation is approximately 9–24% in women undergoing in vitro fertilization. Interestingly, due to containing a...     

Biodegradation of Variable-Chain-Length Alkanes at Low Temperatures by a Psychrotrophic Rhodococcus sp.

The psychrotroph Rhodococcus sp. strain Q15 was examined for its ability to degrade individual n-alkanes and diesel fuel at low temperatures, and its alkane catabolic pathway was investigated by biochemical and genetic techniques. At 0 and 5°C, Q15 mineralized the short-chain alkanes dodecane and hexadecane to a greater extent than that observed for the long-chain alkanes octacosane and dotriacontane. Q15 utilized a broad range of aliphatics (C₁₀ to C₂₁ alkanes, branched alkanes, and a substituted cyclohexane) present in diesel fuel at 5°C. Mineralization of hexadecane at 5°C was significantly greater in both hydrocarbon-contaminated and pristine soil microcosms seeded with Q15 cells than in uninoculated control soil microcosms. The detection of hexadecane and dodecane metabolic intermediates (1-hexadecanol and 2-hexadecanol and 1-dodecanol and 2-dodecanone, respectively) by solid-phase microextraction–gas chromatography-mass spectrometry and the utilization of potential metabolic intermediates indicated that Q15 oxidizes alkanes by both the terminal oxidation pathway and the subterminal oxidation pathway. Genetic characterization by PCR and nucleotide sequence analysis indicated that Q15 possesses an aliphatic aldehyde dehydrogenase gene highly homologous to the Rhodococcus erythropolis thcA gene. Rhodococcus sp. strain Q15 possessed two large plasmids of approximately 90 and 115 kb (shown to mediate Cd resistance) which were not required for alkane mineralization, although the 90-kb plasmid enhanced mineralization of some alkanes and growth on diesel oil at both 5 and 25°C.     

Polyphenols of mature plant,seedling and tissue cultures of Theobroma cacao

The major flavone in mature cocoa leaves is isovitexin, with smaller amounts of vitexin and 7-O-glucosides of apigenin, luteolin and chrysoeriol. F     

Micro-quantitation of lipids in serum-free cell culture media: a critical aspect is the minimization of interference from medium components and chemical reagents

Lipids (fatty acids) at a concentration range of 10-100 microg/L are essential components included in most serum-free cell culture medium formulations. A gas chromatography/mass spectrometry (GC/MS) method for the micro-quantitation of lipids, determined as fatty acid methyl esters (FAMEs), in complex serum-free cell culture media was developed. The interference of derivatizing reagents, extraction solvents and medium additives in the micro-quantitation of lipids was also examined. The results show that the concentration of fatty acids such as palmitic and stearic acids detected in derivatizing reagents or extraction solvents was in the range of 10-230 microg/L. Tween-80, a surfactant and medium additive, produced nearly 20 FAMEs alone when methylated using a derivatizing agent. Moreover, the surfactant Pluronic F-68, a medium additive, interfered in the FAME recovery. Procedures, which include use of low volumetric ratio of reagent to medium and precipitation of the above surfactants, were developed to minimize background FAMEs to levels which do not significantly affect the quantitation of medium lipids and to diminish the interference caused by Pluronic F-68. Fatty acid concentrations in several complex serum-free culture media were quantitated by this method and were very close to the values indicated in their formulations.     

Systemic Induction of Photosynthesis via Illumination of the Shoot Apex Is Mediated Sequentially by Phytochrome B,Auxin and Hydrogen Peroxide in Tomato

Systemic signaling of upper leaves promotes the induction of photosynthesis in lower leaves, allowing more efficient use of light flecks. However, the nature of the systemic signals has remained elusive. Here, we show that preillumination of the tomato (Solanum lycopersicum) shoot apex alone can accelerate photosynthetic induction in distal leaves and that this process is light quality dependent, where red light promotes and far-red light delays photosynthetic induction. Grafting the wild-type rootstock with a phytochome B (phyB) mutant scion compromised light-induced photosynthetic induction as well as auxin biosynthesis in the shoot apex, auxin signaling, and RESPIRATORY BURST OXIDASE HOMOLOG1 (RBOH1)-dependent hydrogen peroxide (H₂O₂) production in the systemic leaves. Light-induced systemic H₂O₂ production in the leaves of the rootstock also was absent in plants grafted with an auxin-resistant diageotropica (dgt) mutant scion. Cyclic electron flow around photosystem I and associated ATP production were increased in the systemic leaves by exposure of the apex to red light. This enhancement was compromised in the systemic leaves of the wild-type rootstock with phyB and dgt mutant scions and also in RBOH1-RNA interference leaves with the wild type as scion. Silencing of ORANGE RIPENING, which encodes NAD(P)H dehydrogenase, compromised the systemic induction of photosynthesis. Taken together, these results demonstrate that exposure to red light triggers phyB-mediated auxin synthesis in the apex, leading to H₂O₂ generation in systemic leaves. Enhanced H₂O₂ levels in turn activate cyclic electron flow and ATP production, leading to a faster induction of photosynthetic CO₂ assimilation in the systemic leaves, allowing plants better adaptation to the changing light environment.As a consequence of their sessile lifestyle, plants have evolved a high capacity for the regulation of physiology, growth, and development that facilitates survival in a constantly changing environment. Environmental stimuli perceived within an organ not only influence morphogenetic and physiological changes within that organ but also generate systemic effects in other organs that are remote from the site of signal perception. This crucial phenomenon is called systemic signaling or systemic regulation. Systemic signaling prepares other tissues of a plant for future challenges that may initially only be sensed by a few local tissues or cells. Several types of systemic responses are known. These include systemic acquired resistance, which is typically activated by pathogens such as viruses, bacteria, and fungi (Fu and Dong, 2013), induced systemic resistance, which is triggered by beneficial soil microorganisms or others (Pieterse and Dicke, 2007), and systemic acquired acclimation, which is initiated by abiotic stresses such as high light, UV radiation, heat, cold, and salinity (Mittler and Blumwald, 2015).The light utilization efficiency of photosynthesis is important for the survival of understory plants and plants growing in canopies. In particular, the efficient use of the energy contained in light (sun) flecks is important because light flecks contribute up to 60% to 80% of photosynthetically active radiation received by understory plants (Pearcy and Seemann, 1990; Leakey et al., 2003, 2005). Earlier studies have shown the existence of systemic regulation of stomatal development and of photosynthesis in developing leaves in response to environmental signals perceived by mature leaves, such as changing irradiance and atmospheric CO₂ conditions (Lake et al., 2002; Coupe et al., 2006; Araya et al., 2008). Phytochome B (phyB) is important in the transmission of the systemic signals that modulate stomatal development in young leaves of Arabidopsis (Arabidopsis thaliana; Casson and Hetherington, 2014). In tomato (Solanum lycopersicum), there are two forms of phyB, phyB1 and phyB2, that work together to mediate red (R) light-induced responses, such as hypocotyl elongation and greening in seedlings (Hauser et al., 1995; Weller et al., 2000).Photosynthesis is completely switched off in the dark, specifically to prevent futile cycling of metabolites through the reductive and oxidative pentose phosphate pathways. Hence, leaves need time to reactivate the enzymes of carbon assimilation after a period of darkness. The time taken to reach maximum net rates of photosynthesis upon illumination is called photosynthetic induction (Walker, 1973). Systemic signaling also has been observed for the regulation of photosynthesis in relation to leaf ontology in understory plants (Montgomery and Givnish, 2008). The uppermost leaves, which are generally the first to receive sunlight, display faster photosynthetic induction times than understory leaves (Bai et al., 2008). Photosynthetic induction in understory leaves is enhanced by the preillumination of upper leaves but not lower leaves, suggesting a directional signal transfer (Hou et al., 2015). While this process allows plants to use the light energy in sun flecks more efficiently, the nature of the systemic signals and their transmission pathways remain largely unresolved. Although systemic signaling between different leaf ranks has been suggested to occur through the xylem (Thorpe et al., 2007) and also via electrical signals (Zimmermann et al., 2009), it is likely that systemic signals also pass through the phloem (Turgeon and Wolf, 2009; Hou et al., 2015). In addition, the phytohormone auxin is produced in the shoot apex and redistributed throughout the shoot by rapid nonpolar phloem transport (Ljung et al., 2001). Changes in the light environment can dramatically alter auxin homeostasis, which is regulated in a light quality- and photoreceptor-dependent manner (Halliday et al., 2009).The photosynthetic electron transport chain exhibits enormous flexibility in the relative rates of NADPH and ATP production in order to accommodate the varying requirements of metabolism (Foyer et al., 2012). Noncyclic, pseudocyclic, and cyclic electron flow (CEF) pathways operate in the photosynthetic electron transport chain to drive the proton gradient across the thylakoid membrane (Allen, 2003). Photosynthetic induction is not only associated with the activation of the light- and thiol-dependent activation of carbon assimilation enzymes but also dependent on a high rate of CEF to drive ATP synthesis (Foyer et al., 1992). Considerable overreduction of the electron transport acceptors occurs during the photosynthetic induction period, and this continues until carbon assimilation can be activated. CEF around PSI, an essential component of photosynthesis, drives the proton gradient in a situation when NADP reduction has reached its highest capacity and this essential electron acceptor is no longer available (Yamori et al., 2015; Yamori and Shikanai, 2016). CEF is particularly sensitive to the reduction-oxidation (redox) status of the chloroplast, which in turn is responsive to cellular redox homeostasis. Oxidants such as hydrogen peroxide (H₂O₂), which are produced by pseudocyclic electron flow in the chloroplasts, play a crucial role in the activation of CEF through modulation of the activity of the NADPH-plastoquinone reductase complex (Strand et al., 2015). Hormone-mediated generation of H₂O₂ also can stimulate CO₂ assimilation (Jiang et al., 2012).Auxins such as indole-3-acetic acid (IAA) generate H₂O₂ (Ivanchenko et al., 2013; Peer et al., 2013) and can regulate CO₂ assimilation (Bidwell and Turner, 1966; Hayat et al., 2009; Peng et al., 2013). Therefore, we used tomato plants to test the hypothesis that the systemic signaling that regulates photosynthetic induction in understory leaves arises from light-induced changes in auxin and H₂O₂ homeostasis involving the modulation of CEF in systemic leaves. We present evidence showing that R light perceived in the shoot apex by a phyB-dependent pathway alters IAA signaling in a systemic manner. IAA signals from the apex, perceived in distal leaves, trigger systemic H₂O₂ production that accelerates photosynthetic induction by increasing CEF-dependent ATP production in the systemic leaves. These findings provide new insights into the elaborate plant regulatory network that allows light adaptation in different organs.     

Position effects due to chromosome breakpoints that map approximately 900 Kb upstream and approximately 1.3 Mb downstream of SOX9 in two patients with campomelic dysplasia

Campomelic dysplasia (CD) is a semilethal skeletal malformation syndrome with or without XY sex reversal. In addition to the multiple mutations found within the sex-determining region Y-related high-mobility group box gene (SOX9) on 17q24.3, several chromosome anomalies (translocations, inversions, and deletions) with breakpoints scattered over 1 Mb upstream of SOX9 have been described. Here, we present a balanced translocation, t(4;17)(q28.3;q24.3), segregating in a family with a mild acampomelic CD with Robin sequence. Both chromosome breakpoints have been identified by fluorescence in situ hybridization and have been sequenced using a somatic cell hybrid. The 17q24.3 breakpoint maps approximately 900 kb upstream of SOX9, which is within the same bacterial artificial chromosome clone as the breakpoints of two other reported patients with mild CD. We also report a prenatal identification of acampomelic CD with male-to-female sex reversal in a fetus with a de novo balanced complex karyotype, 46,XY,t(4;7;8;17)(4qter-->4p15.1::17q25.1-->17qter;7qter-->7p15.3::4p15.1-->4pter;8pter-->8q12.1::7p15.3-->7pter;17pter-->17q25.1::8q12.1-->8qter). Surprisingly, the 17q breakpoint maps approximately 1.3 Mb downstream of SOX9, making this the longest-range position effect found in the field of human genetics and the first report of a patient with CD with the chromosome breakpoint mapping 3' of SOX9. By using the Regulatory Potential score in conjunction with analysis of the rearrangement breakpoints, we identified a candidate upstream cis-regulatory element, SOX9cre1. We provide evidence that this 1.1-kb evolutionarily conserved element and the downstream breakpoint region colocalize with SOX9 in the interphase nucleus, despite being located 1.1 Mb upstream and 1.3 Mb downstream of it, respectively. The potential molecular mechanism responsible for the position effect is discussed.     

The effect of norflurazon on protein composition and chlorophyll organization in pigment–protein complex of Photosystem II

The pyridazinone-type herbicide norflurazon SAN 9789 inhibiting the biosynthesis of long-chain carotenoids results in significant decrease in PS II core complexes and content of light-harvesting complex (LHC) polypeptides in the 29.5–21 kDa region. The Chl a forms at 668, 676, and 690 nm that belong to LHC and antenna part of PS I disappear completely after treatment. The intensity of the Chl b form at 648 nm is sharply decreased in treated seedlings grown under 30 or 100 lx light intensity. The bands of carotenoid absorption at 421, 448 (Chl a), 452, 480, 492, 496 (β-carotene), and 508 nm also disappear. The band shift from 740 to 720 nm and decrease in its intensity relative to the 687 nm emission peak in the low-temperature fluorescence spectrum (77 K) suggests a disturbance of energy transfer from LHC to the Chla form at 710–712 nm.