Phosphate Starvation Inducible Metabolism in Lycopersicon esculentum: II. Characterization of the Phosphate Starvation Inducible-Excreted Acid Phosphatase

Three-day-old suspension cultured cells of Lycopersicon esculentum transferred to a Pi-depleted medium had 2.7 times the excreted acid phosphatase (Apase) activity of cells transferred to a Pi-sufficient medium. Cell growth during this time period was identical for the two treatments. Excreted Apase activity was resolved into two fractions on a Sephadex G-150 column. Most of the phosphate starvation inducible (psi) enhancement in activity was in the lower molecular weight fraction. These two fractions exhibited different substrate versus pH activity profiles. With a native polyacrylamide gel electrophoresis assay, the lower molecular weight fraction resolved into two bands of activity. Both column fractions resolved into the same single band of activity with sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The apparent molecular weight of this enzyme was 57 kilodalton. These data indicate that L. esculentum has at least two isozymes of the psi-excreted Apase and that these isozymes may associate to form high molecular weight aggregates. Labeling studies using [³⁵S]methionine show that the psi response in tomato cells is complex and involves changes in the steady state levels of several excreted proteins.     

拟南芥紫色酸性磷酸酶基因(AtPAPs)对磷饥饿的响应

根据拟南芥基因组测序所获得的信息,对拟南芥2号染色 7个可能的紫色酸性磷酸酶基因进行了cDNA克隆、测序及生物信息学分析,并对其在磷饥饿状态下转录水平的表达模式进行了研究,发现大部分的AtPAPs都是组成性表达的,只有AtPAP9,AtPAP10是诱导表达的,其中AtPAP9的转录产物是磷饥饿重新诱导的,而AtPAP10是磷饥饿诱导增加的。     

Responses of Ruminococcus flavefaciens, a Ruminal Cellulolytic Species, to Nutrient Starvation

Ruminococcus flavefaciens strain C94, a strictly anaerobic, cellulolytic ruminal bacterial species, was grown either in batch or continuous cultures (cellobiose limited or nitrogen limited) at various dilution rates. Washed cell suspensions were incubated anaerobically at 39°C without nutrients for various times up to 24 h. The effects of starvation on direct and viable cell counts, cell composition (DNA, RNA, protein, and carbohydrate), and endogenous production of volatile fatty acids by the cell suspensions were determined. In addition, the effect of the pH of the starvation buffer on direct and viable cell counts was determined. Survival of batch-grown cells during starvation was variable, with an average time for one-half the cells to lose viability (ST₅₀) of 10.9 h. We found with continuous cultures that viable cell counts declined faster when the initial cell suspensions had been grown at faster dilution rates; this effect was more pronounced for suspensions that had been limited by cellobiose (ST₅₀ = 6.6 h at a dilution rate of 0.33 h⁻¹) than for suspensions that had been limited by nitrogen (ST₅₀ = 9.5 h at a dilution rate of 0.33 h⁻¹). With continuous cultures, viable cell counts in all cases declined faster than direct cell counts did. The rates of disappearance of specific cell components during starvation varied with the initial growth conditions, but could not be correlated with the loss of viability. Volatile fatty acid production by starving cells was very low, and acetate was the main product. Starved cells survived longer at pH 7.0 than they did at pH 5.5, and this effect of pH was greater for cellobiose-limited cells (mean ST₅₀ = 7.1 h) than for nitrogen-limited cells (mean ST₅₀ = 12 h). Although it has relatively low ST₅₀ values, R. flavefaciens has sufficient survival abilities to maintain reasonable numbers in domestic animals having maintenance or greater feed intake.     

拟南芥低磷胁迫反应分子机理研究的最新进展

本文综述了拟南芥低磷(Pi)胁迫反应分子机理的最新研究进展,重点介绍了低磷胁迫反应中的SUMOylation途径、转录因子在低磷反应中的功能、Pi平衡调节机制以及磷脂酶在Pi的循环利用过程中的作用,总结了已经鉴定的参与低磷胁迫反应的基因及其可能存在的相互关系。     

拟南芥低磷胁迫反应分子机理研究的最新进展

本文综述了拟南芥低磷(Pi)胁迫反应分子机理的最新研究进展, 重点介绍了低磷胁迫反应中的SUMOylation途径、转录因子在低磷反应中的功能、Pi平衡调节机制以及磷脂酶在Pi的循环利用过程中的作用, 总结了已经鉴定的参与低磷胁迫反应的基因及其可能存在的相互关系。     

Responses of Marine Bacteria Under Starvation Conditions at a Solid-Water Interface

Size changes during starvation of 17 marine bacterial isolates at a solid-water interface and in the liquid phase were examined. Twelve rod-shaped, hydrophilic bacteria decreased in size more rapidly at the solid surface than in the liquid phase, a result parallel to that observed previously for one of the strains at an air-water interface. On the other hand, three rod-shaped, hydrophobic bacteria diminished in size more rapidly in the liquid phase than at the solid-water interface. The rapid size decrease (defined here as the dwarfing phase) in either situation appeared to be an active process which occurred more rapidly when the cells were in an early stage of logarithmic growth at the onset of starvation. Dwarfing was reversibly inhibited by low temperature and low pH but was not inhibited by chloramphenicol. Three coccoidal bacteria showed little tendency to become smaller upon starvation in the liquid phase or at a surface.     

Aluminum Tolerance Acquired during Phosphate Starvation in Cultured Tobacco Cells

Al toxicity in cultured tobacco cells (Nicotiana tabacum L. cv Samsun; nonchlorophyllic cell line SL) has been investigated in nutrient medium. In this system, Al and Fe(II) (ferrous ion) in the medium synergistically result in the accumulation of both Al and Fe, the peroxidation of lipids, and eventually death in cells at the logarithmic phase of growth (+P cells). A lipophilic antioxidant, N,N[prime]-diphenyl-p-phenylenediamine, protected +P cells from the peroxidation of lipids and from cell death, suggesting that a relationship exists between the two. Compared with +P cells, cells that had been starved of Pi (-P cells) were more tolerant to Al, accumulated 30 to 40% less Al and 70 to 90% less Fe, and did not show any evidence of the peroxidation of lipids during Al treatment. These results suggest that -P cells exhibit Al tolerance because their plasma membranes are protected from the peroxidation of lipids caused by the combination of Al and Fe(II). It seems likely that the exclusion of Fe from -P cells might suppress directly Fe-mediated peroxidation of lipids. Furthermore, since -P cells accumulated [beta]-carotene, it is proposed that this carotenoid pigment might function as a radical-trapping antioxidant in the plasma membrane of cells starved of Pi.