ANG II is involved in the LPS-induced production of proinflammatory cytokines in dehydrated rats

We have previously reported results that led us to speculate that ANG II is involved in the LPS-induced production of proinflammatory cytokines, especially under dehydrated conditions. To test this possibility, in this study we examined the effects of an angiotensin-converting enzyme (ACE) inhibitor and an antagonist of the type-1 ANG II receptor (AT(1) receptor) on the LPS-induced production of the proinflammatory cytokines IL-1 and IL-6 in dehydrated rats. A single intravenous injection of LPS induced a marked increase in the expression of IL-1beta mRNA in the liver, an effect that was significantly attenuated by pretreatment with the ACE inhibitor. Furthermore, the ACE inhibitor reduced the LPS-induced increase in the hepatic concentration of IL-1beta protein. When the AT(1)-receptor antagonist was given intravenously before the LPS, the increase in the hepatic concentration of IL-1beta was significantly reduced. Finally, the ACE inhibitor reduced the LPS-induced increase in the plasma concentration of IL-6. These results represent the first in vivo evidence that ANG II and its AT(1) receptor play important roles in the production of proinflammatory cytokines that is induced by LPS under dehydrated conditions.     

Calcium-dependent potentiation of store-operated calcium channels in T lymphocytes

The depletion of intracellular Ca2+ stores triggers the opening of Ca2+ release-activated Ca2+ (CRAC) channels in the plasma membrane of T lymphocytes. We have investigated the additional role of extracellular Ca2+ (Ca02+) in promoting CRAC channel activation in Jurkat leukemic T cells. Ca2+ stores were depleted with 1 microM thapsigargin in the nominal absence of Ca02+ with 12 mM EGTA or BAPTA in the recording pipette. Subsequent application of Ca02+ caused ICRAC to appear in two phases. The initial phase was complete within 1 s and reflects channels that were open in the absence of Ca02+. The second phase consisted of a severalfold exponential increase in current amplitude with a time constant of 5-10 s; we call this increase Ca(2+)-dependent potentiation, or CDP. The shape of the current-voltage relation and the inferred single-channel current amplitude are unchanged during CDP, indicating that CDP reflects an alteration in channel gating rather than permeation. The extent of CDP is modulated by voltage, increasing from approximately 50% at +50 mV to approximately 350% at -75 mV in the presence of 2 mM Ca02+. The voltage dependence of CDP also causes ICRAC to increase slowly during prolonged hyperpolarizations in the constant presence of Ca02+. CDP is not affected by exogenous intracellular Ca2+ buffers, and Ni2+, a CRAC channel blocker, can cause potentiation. Thus, the underlying Ca2+ binding site is not intracellular. Ba2+ has little or no ability to potentiate CRAC channels. These results demonstrate that the store-depletion signal by itself triggers only a small fraction of capacitative Ca2+ entry and establish Ca2+ as a potent cofactor in this process. CDP confers a previously unrecognized voltage dependence and slow time dependence on CRAC channel activation that may contribute to the dynamic behavior of ICRAC.     

Calcium-dependent and calcium-sensitizing pathways in the mature and immature ductus arteriosus

Studies performed in sheep and baboons have shown that after birth, the normoxic muscle media of ductus arteriosus (DA) becomes profoundly hypoxic as it constricts and undergoes anatomic remodeling. We used isolated fetal lamb DA (pretreated with inhibitors of prostaglandin and nitric oxide production) to determine why the immature DA fails to remain tightly constricted during the hypoxic phase of remodeling. Under normoxic conditions, mature DA constricts to 70% of its maximal active tension (MAT). Half of its normoxic tension is due to Ca(2+) entry through calcium L-channels and store-operated calcium (SOC) channels. The other half is independent of extracellular Ca(2+) and is unaffected by inhibitors of sarcoplasmic reticulum (SR) Ca(2+) release (ryanodine) or reuptake [cyclopiazonic acid (CPA)]. The mature DA relaxes slightly during hypoxia (to 60% MAT) due to decreases in calcium L-channel-mediated Ca(2+) entry. Inhibitors of Rho kinase and tyrosine kinase inhibit both Ca(2+)-dependent and Ca(2+)-independent DA tension. Although Rho kinase activity may increase during gestation, immature DA develop lower tensions than mature DA, primarily because of differences in the way they process Ca(2+). Calcium L-channel expression increases with advancing gestation. Under normoxic conditions, differences in calcium L-channel-mediated Ca(2+) entry account for differences in tension between immature (60% MAT) and mature (70% MAT) DA. Under hypoxic conditions, differences in both calcium L-channel-dependent and calcium L-channel-independent Ca(2+) entry, account for differences in tension between immature (33% MAT) and mature (60% MAT) DA. Stimulation of Ca(2+) entry through reverse-mode Na(+)/Ca(2+) exchange or CPA-induced SOC channel activity constrict the DA and eliminate differences between immature and mature DA during both hypoxia and normoxia.     

Investigations into plant biochemical wound-response pathways involved in the production of aphid-induced plant volatiles

Feeding damage to plants by insect herbivores induces the production of plant volatiles, which are attractive to the herbivores natural enemies. Little is understood about the plant biochemical pathways involved in aphid-induced plant volatile production. The aphid parasitoid Diaeretiella rapae can detect and respond to aphid-induced volatiles produced by Arabidopsis thaliana. When given experience of those volatiles, it can learn those cues and can therefore be used as a novel biosensor to detect them. The pathways involved in aphid-induced volatile production were investigated by comparing the responses of D. rapae to volatiles from a number of different transgenic mutants of A. thaliana, mutated in their octadecanoid, ethylene or salicylic acid wound-response pathways and also from wild-type plants. Plants were either undamaged or infested by the peach-potato aphid, Myzus persicae. It is demonstrated that the octadecanoid pathway and specifically the COI1 gene are required for aphid-induced volatile production. The presence of salicylic acid is also involved in volatile production. Using this model system, in combination with A. thaliana plants with single point gene mutations, has potential for the precise dissection of biochemical pathways involved in the production of aphid-induced volatiles.     

Identification of genes involved in the suppression of antibody production from human peripheral blood lymphocytes

Pretreatment with L-leucyl-L-leucine methyl ester (LLME) is a prerequisite for peripheral blood mononuclear cells (PBMCs) to produce antigen-specific antibodies when sensitized with an antigen. Little information, however, is available regarding the mechanisms involved in LLME-induced augmentation of antibody production from PBMCs that are antigen sensitized. In the present study, we attempted to identify the genes involved in the suppression of antibody production from PBMCs that was not treated with LLME, but sensitized with an antigen. Using subtractive screening, we obtained 63 independent genes, including 17 EST genes, that are specific for LLME-nontreated PBMC. Among these genes, the expression of heavy chain ferritin (H-ferritin), CC chemokine ligand 18 (CCL18), and matrix metalloproteinase 12 (MMP12) were augmented in LLME-nontreated PBMCs, suggesting that inflammatory factors might be involved in the suppression of antibody production in LLME-nontreated PBMCs.     

Molecular mechanisms involved in T cell activation. I. Evidence for independent signal-transducing pathways in lymphokine production vs proliferation in cloned cytotoxic T lymphocytes

It is well-established that activated T cells proliferate in response to interleukin 2 (IL 2) and produce various soluble lymphokines such as macrophage-activating factor (MAF) in response to antigen. Prior to investigating the molecular events involved in signaling the initiation of these responses in cloned murine cytotoxic T lymphocytes (CTL), we determined whether these responses could occur independently, and we established for each response the time during which signal transducing mechanisms may function. It was found that this cloned CTL population was in a resting state (G1 phase of cell cycle) 7 days after stimulation with antigen plus IL 2. At this time, the incubation of these resting CTL with IL 2 for 4 to 6 hr resulted in a maximal proliferative response that was not accompanied by the production of MAF. Conversely, the incubation of resting CTL with antigen or lectin (in the absence of IL 2) for at least 8 hr resulted in the maximal production of MAF at 24 hr without inducing a proliferative response. In addition, antigen or lectin, but not IL 2, triggered an immediate (less than 1 min) and sustained (at least 8 hr) mobilization of intracellular calcium. The kinetics of this calcium response paralleled the minimum time (8 hr) that was required for resting CTL to interact with either antigen or lectin in order to produce maximal titers of MAF. These results indicate that proliferation and lymphokine (MAF) production in cloned murine CTL are independent events. In these resting CTL, the signal mechanisms that mediate the production of lymphokines are most likely restricted to the initial 8 hr of stimulation by antigen or lectin and involve the rapid and prolonged mobilization of cytoplasmic calcium. Proliferative signals, however, are probably complete within 4 to 6 hr after stimulation by IL 2 and do not involve readily demonstrable fluxes of cytoplasmic calcium, as determined by the fluorescent calcium probe Quin 2.     

The lipoxygenase pathways are involved in LH-stimulated progesterone production in bovine corpus luteum.

We have examined the effects of endogenous lipoxygenase products on basal progesterone (P4) production by cultured bovine mid-luteal cells. The involvement of lipoxygenase products in the stimulatory effect of LH on luteal cAMP accumulation and P4 production was also examined. Bovine luteal cells from mid-cycle corpora lutea (CL) were exposed for 16 h to a lipoxygenase inhibitor (nordihydroguaiaretic acid: NDGA; 0.33-33 microM). For the last 4 h of incubation, the cells were exposed to LH and/or three different lipoxygenase products, 5-, 12- and 15-hydroxyeicosatetraenoic acid (HETE). NDGA inhibited P4 production by the cells in a dose-dependent manner (P < 0.05). NDGA-reduced P4 production was reversed by the addition of 12-HETE, but not 5- or 15-HETE, whereas 5-, 12- and 15-HETE alone showed no significant effect on P4 production in the intact cells. Furthermore, NDGA (33 microM) blocked the stimulatory action of LH on P4 production (P < 0.05), without changing cAMP accumulation (P > 0.1). When the cells were exposed to 5-, 12- or 15-HETE with LH and NDGA, only 15-HETE maintained the stimulatory effect of LH on P4 production in the cells (P < 0.05). These results suggest that endogenous lipoxygenase products play important roles in P4 production by bovine CL, i.e. basal P4 production is supported by 12-HETE, and LH-stimulated P4 production is partially mediated via the activation of lipoxygenase and subsequent 15-HETE formation downstream of the LH-activated cAMP-PKA-phosphorylation pathway.     

Reaction pathways involved in the production of hydroxyl radicals in thylakoid membrane: EPR spin-trapping study.

It has been suggested that both free metals and reduced ferredoxin (Fd) participate in the light-induced production of hydroxyl radicals (OH*) in thylakoid membranes of chloroplasts. The most direct evidence for the involvement of Fd in OH* formation under physiological conditions was reported by Jakob and Heber (Plant Cell Physiol., 1996, 37, 629-635), who used the oxidation of dimethylsulfoxide to methane sulfinic acid as an indicator of OH* production. We confirmed their conclusions using a more sensitive and reliable EPR spin-trapping method and extended their work by additional findings. Free metal-dependent and ferredoxin-dependent OH* production was studied simultaneously and strong metal chelator Desferal was used to distinguish between these reaction pathways. The participation of protein-bound iron within photosystem I was confirmed by partial suppression of OH* generation in broken chloroplasts by methyl viologen. The enhancement in the production of OH* in thylakoid membranes by externally added ferredoxin can be considered as a straightforward evidence of the involvement of ferredoxin in OH* formation.     

骨髓间充质干细胞向肝细胞分化的相关细胞因子及信号通路的研究进展

骨髓干细胞包括造血干细胞（HSCs）和间充质干细胞（MSCs）,骨髓间充质干细胞（BMSCs）是一类具有自我更新、增殖和多向分化能力的细胞,具有不对称分裂和无限增殖的特点。在肝细胞生长因子（HGF）的作用下,BMSCs可以分化为肝细胞,参与诱导这一分化过程的相关信号通路包括NF-kB信号通路、Notch信号通路、MAPK信号通路、Wnt信号通路和STAT3信号通路。文章主要就BMSCs分化为肝细胞的相关信号通路进行了综述。     

Improvement of bacterial cellulose production by manipulating the metabolic pathways in which ethanol and sodium citrate involved

Nowadays, bacterial cellulose has played more and more important role as new biological material for food industry and medical and industrial products based on its unique properties. However, it is still a difficult task to improve the production of bacterial cellulose, especially a large number of byproducts are produced in the metabolic biosynthesis processes. To improve bacterial cellulose production, ethanol and sodium citrate are added into the medium during the fermentation, and the activities of key enzymes and concentration of extracellular metabolites are measured to assess the changes of the metabolic flux of the hexose monophosphate pathway (HMP), the Embden–Meyerhof–Parnas pathway (EMP), and the tricarboxylic acid cycle (TCA). Our results indicate that ethanol functions as energy source for ATP generation at the early stage of the fermentation in the HMP pathway and the supplementation of ethanol significantly reduces glycerol generation (a major byproduct). While in the EMP pathway, sodium citrate plays a key role, and its supplementation results in the byproducts (mainly acetic acid and pyruvic acid) entering the gluconeogenesis pathway for cellulose synthesis. Furthermore, by adding ethanol and sodium citrate, the main byproduct citric acid in the TCA cycle is also reduced significantly. It is concluded that bacterial cellulose production can be improved by increasing energy metabolism and reducing the formation of metabolic byproducts through the metabolic regulations of the bypasses.     

Signaling pathways involved in MDSC regulation

The immune system has evolved mechanisms to protect the host from the deleterious effects of inflammation. The generation of immune suppressive cells like myeloid derived suppressor cells (MDSCs) that can counteract T cell responses represents one such strategy. There is an accumulation of immature myeloid cells or MDSCs in bone marrow (BM) and lymphoid organs under pathological conditions such as cancer. MDSCs represent a population of heterogeneous myeloid cells comprising of macrophages, granulocytes and dendritic cells that are at early stages of development. Although, the precise signaling pathways and molecular mechanisms that lead to MDSC generation and expansion in cancer remains to be elucidated. It is widely believed that perturbation of signaling pathways involved during normal hematopoietic and myeloid development under pathological conditions such as tumorogenesis contributes to the development of suppressive myeloid cells. In this review we discuss the role played by key signaling pathways such as PI3K, Ras, Jak/Stat and TGFb during myeloid development and how their deregulation under pathological conditions can lead to the generation of suppressive myeloid cells or MDSCs. Targeting these pathways should help in elucidating mechanisms that lead to the expansion of MDSCs in cancer and point to methods for eliminating these cells from the tumor microenvironment.     

TDP-43 affects splicing profiles and isoform production of genes involved in the apoptotic and mitotic cellular pathways

In recent times, high-throughput screening analyses have broadly defined the RNA cellular targets of TDP-43, a nuclear factor involved in neurodegeneration. A common outcome of all these studies is that changing the expression levels of this protein can alter the expression of several hundred RNAs within cells. What still remains to be clarified is which changes represent direct cellular targets of TDP-43 or just secondary variations due to the general role played by this protein in RNA metabolism. Using an HTS-based splicing junction analysis we identified at least six bona fide splicing events that are consistent with being controlled by TDP-43. Validation of the data, both in neuronal and non-neuronal cell lines demonstrated that TDP-43 substantially alters the levels of isoform expression in four genes potentially important for neuropathology: MADD/IG20, STAG2, FNIP1 and BRD8. For MADD/IG20 and STAG2, these changes could also be confirmed at the protein level. These alterations were also observed in a cellular model that successfully mimics TDP-43 loss of function effects following its aggregation. Most importantly, our study demonstrates that cell cycle alterations induced by TDP-43 knockdown can be recovered by restoring the STAG2, an important component of the cohesin complex, normal splicing profile.     

Calcium-dependent mechanisms involved in the modulation of tyrosine hydroxylase by endothelins in the olfactory bulb of normotensive rats

Endothelins (ETs) are widely expressed in the olfactory bulb (OB) and other brain areas where they function as neuropeptides. In a previous study we reported that in the OB ET-1 and ET-3 participate in the long-term regulation of tyrosine hydroxylase (TH), the key enzyme in catecholamine biosynthesis. ETs stimulate TH activity by increasing total and phosphorylated enzyme levels as well as its mRNA. ET-1 response is mediated by a super high affinity ET_A receptor coupled to adenylyl cyclase/protein kinase A and Ca²⁺/calmodulin-dependent protein kinase II (CaMK-II) activation whereas that of ET-3 through an atypical receptor coupled not only to these signaling pathways but also to phospholipase C (PLC)/protein kinase C pathway. Given the participation of PLC and CaMKII in the regulation of TH by ETs in the OB we sought to establish the contribution of calcium to ETs response. Present findings show that calcium released from ryanodine-sensitive channels and extracellular calcium were necessary to stimulate TH by ETs through CaMK-II. On the other hand, intracellular calcium released by the endoplasmic reticulum partially mediated ETs-evoked increase in TH mRNA but calcium influx and CaMK-II inhibition abolished the response. However calcium mechanisms were not involved in ETs-evoked increase in TH protein content. Present findings support that different sources of calcium contribute to the long-term modulation of TH activity and expression mediated by ETs in the rat OB.     

Integrating novel signaling pathways involved in erythropoiesis

Many extrinsic and intrinsic factors control the development of red blood cells from committed progenitors, with the Erythropoietin-receptor (Epo-R) signaling network being the primary controlling molecular hub. Although much is understood about erythroid signaling pathways, new and intriguing factors that influence different aspects of erythroid cell development are still being uncovered. New extrinsic effectors include hypoxia and polymeric IgA1 (pIgA1), and new Epo-R signaling pathway components include Lyn/Cbp and Lyn/Liar. Hypoxia directly activates committed erythroid progenitors to expand, whereas pIgA1 activates the Akt and MAP-Kinase (MAPK) pathways through transferrin receptors on more mature erythroid cells. The Lyn/Cbp pathway controls the activity and protein levels of Lyn through recruitment of Csk and SOCS1, as well as feeding into the control of other pathways mediated by recruitment of ras-GAP, PI3-kinase, PLCγ, Fes, and EBP50. Nuclear/cytoplasmic shuttling of Lyn and other signaling molecules is influenced by Liar and results in regulation of their intersecting signaling pathways. The challenge of future research is to flesh out the details of these new signaling regulators/networks and integrate their influences during the different stages of erythropoiesis.     

Phospholipid scramblase activation pathways in lymphocytes.

In erythrocytes and platelets, activation of a nonspecific lipid flipsite termed the scramblase allows rapid, bidirectional transbilayer movement of all types of phospholipids. When applied to lymphoid cells, scramblase assays reveal a similar activity, with scrambling rates intermediate between those seen in platelets and erythrocytes. Scrambling activity initiated in lymphoid cells by elevation of intracellular Ca(2+) proceeds after a lag not noted in platelets or erythrocytes. The rates of transbilayer movement of phosphatidylserine and phosphatidylcholine analogues are similar whether the scramblase is activated by elevated internal Ca(2+) or by apoptosis. Elevation of internal Ca(2+) levels in apoptotic cells does not result in an additive increase in the rate of lipid movement. In lymphoid cells from a patient with Scott syndrome, scramblase cannot be activated by Ca(2+), but is induced normally during apoptosis. These findings suggest that Ca(2+) and apoptosis operate through different pathways to activate the same scramblase.     

Dissecting the signaling pathways involved in the function of sperm flagellum

The mammalian flagellum is a specific type of motile cilium required for sperm motility and male fertility. Effective flagellar movement is dependent on axonemal function, which in turn relies on proper ion homeostasis within the flagellar compartment. This ion homeostasis is maintained by the concerted function of ion channels and transporters that initiate signal transduction pathways resulting in motility changes. Advances in electrophysiology and super-resolution microscopy have helped to identify and characterize new regulatory modalities of the mammalian flagellum. Here, we discuss what is currently known about the regulation of flagellar ion channels and transporters that maintain sodium, potassium, calcium, and proton homeostasis. Identification of new regulatory elements and their specific roles in sperm motility is imperative for improving diagnostics of male infertility.