The effects of salt stress on photosynthetic electron transport and thylakoid membrane proteins in the cyanobacterium Spirulina platensis

The response of Spirulina (Arthrospira) platensis to high salt stress was investigated by incubating the cells in light of moderate intensity in the presence of 0.8 M NaCl. NaCl caused a decrease in photosystem II (PSII) mediated oxygen evolution activity and increase in photosystem I (PSI) activity and the amount of P700. Similarly maximal efficiency of PSII (Fv/Fm) and variable fluorescence (Fv/Fo) were also declined in salt-stressed cells. Western blot analysis reveal that the inhibition in PSII activity is due to a 40 % loss of a thylakoid membrane protein, known as D1, which is located in PSII reaction center. NaCl treatment of cells also resulted in the alterations of other thylakoid membrane proteins: most prominently, a dramatic diminishment of the 47-kDa chlorophyll protein (CP) and 94-kDa protein, and accumulation of a 17-kDa protein band were observed in SDS-PAGE. The changes in 47-kDa and 94-kDa proteins lead to the decreased energy transfer from light harvesting antenna to PSII, which was accompanied by alterations in the chlorophyll fluorescence emission spectra of whole cells and isolated thylakoids. Therefore we conclude that salt stress has various effects on photosynthetic electron transport activities due to the marked alterations in the composition of thylakoid membrane proteins.     

Native folding of aggregation-prone recombinant proteins in Escherichia coli by osmolytes, plasmid- or benzyl alcohol-overexpressed molecular chaperones

When massively expressed in bacteria, recombinant proteins often tend to misfold and accumulate as soluble and insoluble nonfunctional aggregates. A general strategy to improve the native folding of recombinant proteins is to increase the cellular concentration of viscous organic compounds, termed osmolytes, or of molecular chaperones that can prevent aggregation and can actively scavenge and convert aggregates into natively refoldable species. In this study, metal affinity purification (immobilized metal ion affinity chromatography [IMAC]), confirmed by resistance to trypsin digestion, was used to distinguish soluble aggregates from soluble nativelike proteins. Salt-induced accumulation of osmolytes during induced protein synthesis significantly improved IMAC yields of folding-recalcitrant proteins. Yet, the highest yields were obtained with cells coexpressing plasmid-encoded molecular chaperones DnaK-DnaJ-GrpE, ClpB, GroEL-GroES, and IbpA/B. Addition of the membrane fluidizer heat shock-inducer benzyl alcohol (BA) to the bacterial medium resulted in similar high yields as with plasmid-mediated chaperone coexpression. Our results suggest that simple BA-mediated induction of endogenous chaperones can substitute for the more demanding approach of chaperone coexpression. Combined strategies of osmolyte-induced native folding with heat-, BA-, or plasmid-induced chaperone coexpression can be thought to optimize yields of natively folded recombinant proteins in bacteria, for research and biotechnological purposes.     

Alpha-ketoglutarate dehydrogenase: a target and generator of oxidative stress

Alpha-ketoglutarate dehydrogenase (alpha-KGDH) is a highly regulated enzyme, which could determine the metabolic flux through the Krebs cycle. It catalyses the conversion of alpha-ketoglutarate to succinyl-CoA and produces NADH directly providing electrons for the respiratory chain. alpha-KGDH is sensitive to reactive oxygen species (ROS) and inhibition of this enzyme could be critical in the metabolic deficiency induced by oxidative stress. Aconitase in the Krebs cycle is more vulnerable than alpha-KGDH to ROS but as long as alpha-KGDH is functional NADH generation in the Krebs cycle is maintained. NADH supply to the respiratory chain is limited only when alpha-KGDH is also inhibited by ROS. In addition being a key target, alpha-KGDH is able to generate ROS during its catalytic function, which is regulated by the NADH/NAD+ ratio. The pathological relevance of these two features of alpha-KGDH is discussed in this review, particularly in relation to neurodegeneration, as an impaired function of this enzyme has been found to be characteristic for several neurodegenerative diseases.     

Induction and regulation of Fas-mediated apoptosis in human thyroid epithelial cells

Fas-mediated apoptosis has been proposed to play an important role in the pathogenesis of Hashimoto's thyroiditis. Normal thyroid cells are resistant to Fas-mediated apoptosis in vitro but can be sensitized by the unique combination of interferon-gamma and IL-1beta cytokines. We sought to examine the mechanism of this sensitization and apoptosis signaling in primary human thyroid cells. Without the addition of cytokines, agonist anti-Fas antibody treatment of the thyroid cells resulted in the cleavage of proximal caspases, but this did not lead to the activation of caspase 7 and caspase 3. Apoptosis associated with the cleavage of caspases 7, 3, and Bid, and the activation of mitochondria in response to anti-Fas antibody occurred only after cytokine pretreatment. Cell surface expression of Fas, the cytoplasmic concentrations of procaspases 7, 8, and 10, and the proapoptotic molecule Bid were markedly enhanced by the presence of the cytokines. In contrast, P44/p42 MAPK (Erk) appeared to provide protection from Fas-mediated apoptosis because an MAPK kinase inhibitor (U0126) sensitized thyroid cells to anti-Fas antibody. In conclusion, Fas signaling is blocked in normal thyroid cells at a point after the activation of proximal caspases. Interferon-gamma/IL-1beta pretreatment sensitizes human thyroid cells to Fas-mediated apoptosis in a complex manner that overcomes this blockade through increased expression of cell surface Fas receptor, increases in proapoptotic molecules that result in mitochondrial activation, and late caspase cleavage. This process involves Bcl-2 family proteins and appears to be compatible with type II apoptosis regulation.     

Calcium signaling in isolated skeletal muscle fibers investigated under “silicone voltage-clamp” conditions

In skeletal muscle, release of calcium from the sarcoplasmic reticulum (SR) represents the major source of cytoplasmic Ca²⁺ elevation. SR calcium release is under the strict command of the membrane potential, which drives the interaction between the voltage sensors in the t-tubule membrane and the calcium-release channels. Either detection or control of the membrane voltage is thus essential when studying intracellular calcium signaling in an intact muscle fiber preparation. The silicone-clamp technique used in combination with intracellular calcium measurements represents an efficient tool for such studies. This article reviews some properties of the plasma membrane and intracellular signals measured with this methodology in mouse skeletal muscle fibers. Focus is given to the potency of this approach to investigate both fundamental aspects of excitation-contraction coupling and potential alterations of intracellular calcium handling in some muscle diseases.     

Dormant Buds and Adventitious Root Formation by <Emphasis Type="Italic">Vitis</Emphasis> and Other Woody Plants

Viticulture has historically depended upon clonal propagation of winegrape, tablegrape, and rootstock cultivars. Dependence on clonal propagation is perpetuated by consumer preference, legal regulations, a reproductive biology that is incompatible with sustaining genetic lines, and the fact that grapevine breeding is a slow process. Adventitious root formation is a key component to successful clonal propagation. In spite of this fact, grapevine has not been a centerpiece for adventitious root research. Dormant woody canes represent complex assemblages of tissues and organs. Factors that further contribute to such complexity include levels of endogenous plant growth regulators, the extent and duration of dormancy, carbohydrate storage, transport, the presence or absence of dormant buds or emergent shoots, and preconditioning treatments. For the above reasons, the mechanisms driving adventitious root formation by grapevine and other woody cuttings are poorly understood. We present results indicating that the dormant bud on cane cuttings from a non-recalcitrant to root Vitis vinifera cultivar, cv. Cabernet Sauvignon, slows or inhibits adventitious root emergence. In contrast to Cabernet Sauvignon, removal of the dormant bud from cane cuttings of a recalcitrant to root hybrid rootstock (V. berlandieri × V. riparia cv. 420A) and an intermediate to root hybrid rootstock (V. riparia × V. rupestris cv. 101-14) had no influence on adventitious root emergence. Reciprocal transplanting of nodes containing dormant buds among all three cultivars did not affect rooting behavior. Our results indicate that the commonly held belief that bud removal diminishes adventitious root emergence is not true.     

Neuronal-induced and glutamate-dependent activation of glial glutamate transporter function

The activity of high-affinity glutamate transporters is essential for the normal function of the mammalian central nervous system. Using a combined pharmacological, confocal immunocytochemical, enzyme-based microsensor and fluorescence imaging approach, we examined glutamate uptake and transporter protein localization in single astrocytes of neuron-containing and neuron-free microislands prior to pre-synaptic transmitter secretion and during functional neuronal activity. Here, we report that the presence or absence of neurons strikingly affects the uptake capacity of the astroglial glutamate transporters GLT1 and GLAST1. Induction of transporter function is activated by neurons and this effect is mimicked by pre-incubation of astrocytes with micromolar concentrations of glutamate. Moreover, increased glutamate transporter activation is reproduced by endogenous release of glutamate via activation of neuronal nicotinic receptors. The increase in transport activity is dependent on neuronal release of glutamate, is associated with the local redistribution (clustering) of GLT1 and GLAST1 but is independent of transporter synthesis and of glutamate receptor activation. Together, these results suggest an activity-dependent neuronal feedback system for rapid astroglial glutamate transporter regulation where neuron-derived glutamate is the physiological signal that triggers transporter function.     

Characterization of Regulatory B Cells in Graves’ Disease and Hashimoto’s Thyroiditis

A hallmark of regulatory B cells is IL-10 production, hence their designation as IL-10⁺ B cells. Little is known about the ability of self-antigens to induce IL-10⁺ B cells in Graves’ disease (GD), Hashimoto’s thyroiditis (HT), or other autoimmune disease. Here we pulsed purified B cells from 12 HT patients, 12 GD patients, and 12 healthy donors with the thyroid self-antigen, thyroglobulin (TG) and added the B cells back to the remaining peripheral blood mononuclear cells (PBMCs). This procedure induced IL-10⁺ B-cell differentiation in GD. A similar tendency was observed in healthy donors, but not in cells from patients with HT. In GD, B cells primed with TG induced IL-10-producing CD4⁺ T cells. To assess the maximal frequency of inducible IL-10⁺ B cells in the three donor groups PBMCs were stimulated with PMA/ionomycin. The resulting IL-10⁺ B-cell frequency was similar in the three groups and correlated with free T₃ levels in GD patients. IL-10⁺ B cells from both patient groups displayed CD25 or TIM-1 more frequently than did those from healthy donors. B-cell expression of two surface marker combinations previously associated with regulatory B-cell functions, CD24^hiCD38^hi and CD27⁺CD43⁺, did not differ between patients and healthy donors. In conclusion, our findings indicate that autoimmune thyroiditis is not associated with reduced frequency of IL-10⁺ B cells. These results do not rule out regulatory B-cell dysfunction, however. The observed phenotypic differences between IL-10⁺ B cells from patients and healthy donors are discussed.     

The light microscopic demonstration of hydroperoxidase-positive Phi bodies and rods in leukocytes in acute myeloid leukemia.

Unique fusiform or spindle-shaped particles (Phi bodies) and rods with hydroperoxidase (catalase and/or peroxidase) activity are present in human granulocyte precursors only in acute myelogenous leukemia (AML). These newly recognized particles are much more numerous and prominent than Auer rods. They may be rapidly and readily identified using the microscope in marrow or peripheral blood films when the procedures recommended in this paper for fixation, incubation for hydroperoxidase demonstration in 3,3'-diaminobenzidine (DAB)/H2O2 medium, copper salt treatment and counterstaining (optional) with the Papanicolaou method are employed. Films prepared in the same manner but treated with benzidine/H2O2 medium for myeloperoxidase did not reveal these particles. We believe that Phi bodies are pathognomonic of AML since they are almost invariably present in AML patients with active disease. Their presence serves to distinguish AML from acute lymphocytic leukemia and from chronic granulocytic leukemia in blast crisis. Since the particles disappear in disease remission and reappear upon relapse, the recommended procedure is not only useful in diagnosis but in guiding therapy. When a very rapid diagnosis is needed, it is not necessary to counterstain the preparations, but the nuclei, cytoplasm and plasmalemma can readily be observed in the granulocyte precursors when they are counterstained by the Papanicolaou method. This treatment does not diminish the clarity of the Phi bodies and rods which stain by virtue of their peroxidatic activity. This cytochemical diagnostic procedure should be considered for adoption by hematology laboratories.