Nitrogen resorption from senescing leaves of three salt marsh plant species

Seasonalvariation in leaf nitrogen of mature green and senescent leaves and nitrogenresorption efficiency in three plants (Spartina maritima, Halimioneportulacoides and Arthrocnemum perenne) of aTagus estuary salt marsh are reported. Total nitrogen concentrations in greenand senescent leaves were higher during winter (December and March). Soilinorganic nitrogen availability showed an opposite pattern with higherconcentrations during summer (June and September) when total leaf biomass washigher. Nitrogen resorption efficiency ranged between 31 and 76% andH. portulacoides was the plant that better minimizednitrogen loss by this process. Nitrogen resorption occurred mainly from thesoluble protein pool, although other fractions must have been broken down duringthe resorption process. No significant seasonal variation in nitrogen resorptionefficiency and no relation to leaf total nitrogen or soil nitrogen availabilitywere found. This suggests that the efficiency of the resorption process is notdetermined by the plant nitrogen status nor by the availability of the nutrientin the soil. Nevertheless, resorption from senescing leaves may play animportant role in the nitrogen dynamics of salt marsh plants and reduce thenitrogen requirements for plant growth.     

The impact of calmodulin on the cell cycle analyzed in a novel human cellular genetic system

Calmodulin (CaM) is the principle mediator of the Ca²⁺ signal in all eukaryotic cells. A huge variety of basic cellular processes including cell cycle control, proliferation, secretion and motility, among many others are governed by CaM, which regulates activities of myriads of target proteins. Mammalian CaM is encoded by three genes localized on different chromosomes all producing an identical protein. In this study, we have generated HeLa human cancer cells conditionally expressing CaM in a genetic background with all three genes inactivated by CRISPR/Cas9. We demonstrate that downregulation of ectopically expressed CaM is achieved after 120 h, when cells are arrested in the M phase of the cell cycle. We show for the first time that CaM downregulation in human cancer cells is followed by a multinucleated senescent state as indicated by expression of β-galactosidase as well as cell morphology typical for senescent cells. Our newly generated genetic system may be useful for the analysis of other CaM regulated processes in eukaryotic cells in the absence of endogenous CaM genes.     

Curcumin-treated cancer cells show mitotic disturbances leading to growth arrest and induction of senescence phenotype

Cellular senescence is recognized as a potent anticancer mechanism that inhibits carcinogenesis. Cancer cells can also undergo senescence upon chemo- or radiotherapy. Curcumin, a natural polyphenol derived from the rhizome of Curcuma longa, shows anticancer properties both in vitro and in vivo. Previously, we have shown that treatment with curcumin leads to senescence of human cancer cells. Now we identified the molecular mechanism underlying this phenomenon. We observed a time-dependent accumulation of mitotic cells upon curcumin treatment. The time-lapse analysis proved that those cells progressed through mitosis for a significantly longer period of time. A fraction of cells managed to divide or undergo mitotic slippage and then enter the next phase of the cell cycle. Cells arrested in mitosis had an improperly formed mitotic spindle and were positive for γH2AX, which shows that they acquired DNA damage during prolonged mitosis. Moreover, the DNA damage response pathway was activated upon curcumin treatment and the components of this pathway remained upregulated while cells were undergoing senescence. Inhibition of the DNA damage response decreased the number of senescent cells. Thus, our studies revealed that the induction of cell senescence upon curcumin treatment resulted from aberrant progression through the cell cycle. Moreover, the DNA damage acquired by cancer cells, due to mitotic disturbances, activates an important molecular mechanism that determines the potential anticancer activity of curcumin.     

The value of a leaf

Summary The value of a leaf to a plant depends on the fate of its exported assimilates. When these are translocated and used in the growth of new leaves they contribute to further carbon assimilation. The result is that their value to the plant is greatest while they are young. In contrast, when assimilates are translocated to storage, assimilates produced early and late in the life of a leaf are of equal value. This arguments is developed in relation to the optimal distribution of mineral resources and defenses during the life of leaves.     

2,4‑Di‑tert‑butylphenol,a potential HDAC6 inhibitor,induces senescence and mitotic catastrophe in human gastric adenocarcinoma AGS cells

The natural product 2,4?di?tert?butylphenol (DTBP) has a wide spectrum of biological functions, including anticancer activities, although the underlying mechanisms are poorly understood. Here, we found that DTBP induces senescence in human gastric adenocarcinoma AGS cells as evidenced by upregulation of p21 and Rb and increased β?galactosidase activity. DTBP also induces mitotic catastrophe and generates multinucleated cells, which is accompanied by an increase in the proportion of polymerized tubulin, possibly caused by inhibition of HDAC6 enzyme activity. In silico docking analysis showed that DTBP docked at the entrance of the ligand-binding pocket of the HDAC6 enzyme. Accordingly, DTBP represents a promising lead structure for the development of HDAC6 inhibitors, with an improvement in specificity conferred by modification of the cap group. We propose for the first time that the underlying mechanism of the anticancer activity of DTBP is attributed to inhibition of HDAC6 activity.     

Pollinia-borne chemicals that induce early postpollination effects in Dendrobium flowers move rapidly into agar blocks and include ACC and compounds with auxin activity

The early visible effects of pollination in orchids are likely due to pollinia-borne chemicals. In Dendrobium we tested whether such compounds were water soluble and would diffuse in solid-aqueous phase, and determined both 1-aminocyclopropane-1-carboxylic acid (ACC) concentrations and auxin activity. Following pollination, the flower peduncle showed epinastic movement, followed by yellowing of the flower lip, flower senescence and ovary growth. Placing pollinia on agar blocks for 3, 6, 9 or 12 h, prior to transferring them to the stigma, increased the time to these early postpollination effects or prevented them. Placing agar blocks that had been used for contact with the pollinia on the stigma also induced the early postpollination effects. The concentrations of ACC, the direct precursor of ethylene, in pollinia was lower the longer the pollinia had been in contact with the agar blocks, whilst the ACC content in the agar blocks increased with the period of contact. The auxin activity of the agar blocks also increased with the time of contact with pollinia. It is concluded that chemicals in the pollinia are responsible for the early visible postpollination effects, and that these (a) rapidly diffuse in aqueous media, and (b) comprise at least ACC and compounds with auxin activity. The idea is discussed that ACC plus auxin is adequate for the production of the early postpollination effects.     

Phospholipase D in cellular senescence

Cellular senescence appears to be an important part of organismal aging. Cellular senescence is characterized by flattened enlarged morphology, inhibition of DNA replication in response to growth factors, inability to phosphorylate the pRb tumor suppressor protein, inability to produce c-fos or AP-1 and overexpression of a variety of genes, notably p21 (CIP-1/WAF-1) and p16^INK. It is now clear that certain early mitotic signals become defective with the onset of senescence. Among these is the PLD/PKC pathway. Evidence suggests that activation of PLD and PKC is critical for mitogenesis. Recent data suggest that the defect in PLD/PKC in cellular senescence is a result of elevated cellular ceramide levels which inhibit PLD activation. It appears that the elevated ceramide is a result of neutral sphingomyelinase activation. Ceramide acts to inhibit the activation of PLD by possibly three mechanisms, inhibiting activation by Rho, translocation to the membrane and gene expression. Addition of ceramide to young cells not only inhibits PLD but also recapitulates all the standard measures of cellular senescence as described above.     

Down-regulation of senescence marker protein 30 by iron-specific chelator deferoxamine drives cell senescence

To our knowledge, this is the first study to report down-regulation of senescence marker protein 30 (SMP30) by iron-specific chelator deferoxamine (DFO) on FAO cell senescence, using a DNA microarray. Furthermore, DFO treatment increased senescence marker β-galactosidase activity, whereas this activity was attenuated by overexpression of SMP30. Our data suggested that down-regulation of SMP30 drives cell senescence in iron-chelated condition.