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1.
Ethylene production of habituated and auxin-requiring tobacco ( Nicotiana tabacum L. cv. Xanthi) callus cultures were compared. More ethylene was produced by auxinrequiring i.e. auxin-heterotrophic cultures than by habituated ones. Treatment with 2,4-dichlorophenoxyacetic acid increased the ethylene evolution of habituated cultures over the range 10−7 to 10−4 M , which suggests that the higher ethylene production of auxin-dependent callus is caused by the 2,4-D in the medium. The IAA levels depended on the age of both types of callus cultures. 相似文献
2.
C. Kevers B. Bisbis F. Le Dily J. P. Billard C. Huault Th. Gaspar 《In vitro cellular & developmental biology. Plant》1995,31(2):122-126
The transfer of light-cultured green normal (N) and white habituated (HNO) sugarbeet callus to darkness reduced the growth
of N callus and improved growth and delayed necrosis in the HNO callus. The decrease of dry matter of N callus under darkness
was accompanied by a reduced content of carotenoids and by decreased CO2 fixation, which was compensated by an increased dependency on externally supplied sucrose. The levels of some organic nitrogen
compounds such as glutamate, proline, and free polyamines were not affected by transfer to darkness of N or HNO callus. Darkness
decreased ethylene emissions in both callus types. In the HNO callus, the sucrose growth dependency and the CO2 fixation were unaffected by darkness. Chlorophylls were absent both in light and darkness, whereas some carotenoids were
accumulated in the HNO callus only in dark conditions. In another connection, a significant increase of peroxidase activity,
which did not occur in the N callus, was induced by darkness in the HNO callus. A decreased content of thio-barbituric acid
(TBA)-reactive substances was measured in the HNO callus transferred to darkness, whereas an increase was noticed in the N
callus placed in the same conditions. These metabolic changes and the reduction of cellular damage in darkness revealed light-induced
stress reactions leading to necrosis and to reduced growth of HNO callus. It appeared that darkness allowed the HNO callus
to avoid the photooxidation stress. Therefore, the favorable effect of darkness on HNO growth might be explained by the suppression
of photooxidative damage due to the absence of carotenoids. The higher peroxidase activity in the HNO callus maintained in
darkness raised the problem of heme synthesis in this heterotrophic callus. 相似文献
3.
经硫酸铵分部沉淀、SephacrylS-300和DEAE-纤维素柱层析纯化了小球藻RubisCO,得率为15%,比活力达1.232μmolCO2ms-1min-1,分子量是500kD,它和菠菜叶片RubisCO在分子量、亚基组成和免疫特性等方面相似,反映RubisCO在高等和低等植物中有较高的同源性。自养小球藻RubisCO占细胞可溶性蛋白质的24%。而异养转变后的小球藻细胞内不含RubisCO。异养小球藻向自养生长转变过程中,20h后细胞内叶绿素含量逐渐增加,24h时细胞内出现RubisCO,24h后大量增加,至41h时含量达最高峰;标志着小球藻细胞光合作用能力的恢复和加强。 相似文献
4.
Carbon flows in the Westerschelde estuary (The Netherlands) evaluated by means of an ecosystem model (MOSES) 总被引:11,自引:11,他引:0
The autotrophic production and heterotrophic consumption of organic matter in the Westerschelde, a highly turbid and eutrophic estuary in the Southwest Netherlands is examined by means of a dynamic simulation model. The model describes the ecologically relevant processes in thirteen spatial compartments and adequately fits most observed data.Three autotrophic processes are included in the model. Net pelagic photosynthetic production is relatively low (average 41 gC m–2 yr–1) and three spatial compartments near the turbidity maximum zone are respiratory sinks of phytoplankton biomass. According to the model, net phytobenthic primary production is more important than pelagic primary production in the upstream half of the Westerschelde. On the scale of the entire estuary, benthic primary production amounts to about 60% of pelagic primary production. Water-column nitrification, which is very important in the nitrogen cycle, is most pronounced near the turbidity zone where it accounts for the major autotrophic fixation of carbon (up to 27 g C m–2 yr–1). Viewed on the scale of the total estuary, however, the process is not very important.Less than 20% of total organic carbon input to the estuary is primary produced, the remainder is imported from waste discharges and from the river.The degree of heterotrophy of the Westerschelde estuary proved to be one of the highest yet reported. On average 380 g carbon per square metre is net lost per year (range 200–1200 gC m–2 yr–1). The yearly community respiration (bacterial mineralization, respiration of higher trophic levels and sedimentation) is 4 to 35 times (estuarine mean of 6) higher than the net production. This degree of heterotrophy is highest near the turbidity maximum and generally decreases from the freshwater to the seaward boundary. About 75% of all carbon losses can be ascribed to pelagic heterotrophic processes; the sediment is only locally important.Mineralisation rates are highest in the turbidity region, but as only a fraction of total carbon resides here, less than 20% of all organic carbon is lost in this part of the estuary. This result is in contradiction with a previous budget of the estuary, based on data of the early seventies, where more than 80% of all carbon was estimated to be lost in the turbidity zone. Part of this discrepancy is probably caused by changes that have occurred in the estuary since that time.Due to the high heterotrophic activity, nearly all imported and in situ produced carbon is lost in the estuary itself and the Westerschelde is an insignificant source of organic matter to the coastal zone.The model estuary acts as a trap for reactive organic matter, both from the land, from the sea or in situ produced. Internal cycling, mainly in the water column, results in the removal of most of the carbon while the more refractory part is exported to the sea. 相似文献
5.
A new paradigm for producing astaxanthin from the unicellular green alga Haematococcus pluvialis
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Zhen Zhang Baobei Wang Qiang Hu Milton Sommerfeld Yuanguang Li Danxiang Han 《Biotechnology and bioengineering》2016,113(10):2088-2099
6.
Survival of the green alga Scenedesmus acuminatus Lagerh. in complete darkness was studied in axenic batch cultures at 7°C and 22°C for three months. The decrease in cell numbers was insensitive to temperature and slower than the loss of dry weight. However, the lag phase before cells began to lyse was more than twice as long at 7° C than at 22°C. The decline in cellular carbohydrates and proteins occurred in two phases. During the first 3-4 days, the decrease in cellular carbohydrate levels was significantly accelerated and temperature-sensitive. Pyrenoids disappeared within 5 days of darkness. Proteins showed 20-fold higher degradation rates at 22°C than at 7°C during the first 4 days. Thereafter, the rates of carbohydrate and protein decomposition were slow and temperature-independent. By contrast, lipids degraded only little at virtually constant and temperature-insensitive rates over the entire experimental period. After three months of dark incubation, about 40% of the remaining cells had retained their growth potential. However, the lag phase, after which cell division was resumed when exposed to light, increased with the duration of the previous dark period. The decrease in photo synthetic potential, which was more pronounced at 22° C than at 7° C, was apparent both in declining maximum assimilation numbers and maximum quantum yields. Cellular chlorophyll a concentrations in surviving cells decreased only slightly. We conclude that the primary means by which S. acuminatus survives extended dark periods is by reduction of catabolic reactions. This was suggested by the slow loss of cell weight. No evidence of significant heterotrophic acetate uptake was found. The initial temperature-dependence of most observed processes indicates that in natural environments chances for survival of algae are augmented by the prevailing low water temperatures. 相似文献
7.
Amphora coffeaeformis (Ag.) Kütz. var. perpusilla (Grun.) Cleve took up glucose by an inducible transport system. The system was induced by d -fructose, d -mannose, as well as glucose. Some d -pentoses also induced a glucose uptake system but it may not be the same one as that induced by hexose. d -fructose, d -mannose and 2-deoxy-d -glucose inhibited 2 mM glucose uptake at equimolar concentration, but d -pentoses did not. The uptake system decayed in ca. 5 h in the absence of glucose. The half-saturation constant for uptake, K8 was ca. 0.1 mM glucose with a maximum uptake rate, Vmax= 0.4 nmol/106 cells-min?1. 相似文献
8.
9.
Three axenic polar sea ice diatom cultures were subjected to a 30 day simulated summer-winter transition in which light and temperature were decreased and salinity was increased to mimic seasonal changes previously reported for ice-covered polar seas. The diatoms responded to these changes by a reduction in cellular metabolism as indicated by: 1) A decline in growth rate and photosynthetic rate; 2) a decrease in cellular ATP; and 3) the storage and subsequent utilization of endogenous carbon reserves. In addition, heterotrophic potential of the three clones increased by as much as 60-fold. In some cases, the decrease in light intensity characteristic of the onset of polar winter was alone sufficient to trigger these physiological changes. 相似文献
10.
Paul D. Nabity Greg A. Barron-Gafford Noah K. Whiteman 《Current biology : CB》2021,31(6):1344-1350.e3
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