光照-温度交互作用及不同氮源对拟柱孢藻生长的影响

为探讨不同环境因子对拟柱孢藻(Cylindrospermopsis raciborskii)生长的影响,对从广东省镇海水库分离的2株拟柱孢藻在不同的温度和光照组合,及不同氮源条件下的生长进行了研究。结果表明,在3种光强下,拟柱孢藻N1和N8藻株的生长随温度的上升而增加,均在28℃高光强下达到最大比生长速率,而N8藻株对低温的适应能力要高于N1藻株。拟柱孢藻N1和N8在各硝态氮浓度下均能正常生长,但仅能在中低浓度的铵态氮和尿素氮中生长,高浓度(128~247 mg L–1)的铵态氮和尿素氮会显著抑制藻细胞生长;在3种氮源下,N1藻株的比生长速率均显著大于N8藻株,这说明N1藻株对不同氮源的利用能力要高于N8藻株。因此,广东省的拟柱孢藻具株系多样性,喜好高温,适应较宽的光照范围,并可利用多种氮源用于生长,这可能是该地区拟柱孢藻水华频发的原因。     

Strong associations between plant genotypes and bacterial communities in a natural salt marsh

Although microbial communities have been shown to vary among plant genotypes in a number of experiments in terrestrial ecosystems, relatively little is known about this relationship under natural conditions and outside of select model systems. We reasoned that a salt marsh ecosystem, which is characterized by twice‐daily flooding by tides, would serve as a particularly conservative test of the strength of plant–microbial associations, given the high degree of abiotic regulation of microbial community assembly resulting from alternating periods of inundation and exposure. Within a salt marsh in the northeastern United States, we characterized genotypes of the foundational plant Spartina alterniflora using microsatellite markers, and bacterial metagenomes within marsh soil based on pyrosequencing. We found significant differences in bacterial community composition and diversity between bulk and rhizosphere soil, and that the structure of rhizosphere communities varied depending on the growth form of, and genetic variation within, the foundational plant S. alterniflora. Our results indicate that there are strong plant–microbial associations within a natural salt marsh, thereby contributing to a growing body of evidence for a relationship between plant genotypes and microbial communities from terrestrial ecosystems and suggest that principles of community genetics apply to this wetland type.     

植物氨基酸转运子研究进展

氨基酸是高等植物氮素同化产物长距离运输及在组织间分配的主要形式,通过跨膜转运的方式在植物体内进行运输。氨基酸转运子是位于生物膜上吸收及转运氨基酸的蛋白家族,对植物氮素营养具有重要贡献。本文对植物氨基酸转运子的表达、调控及其与氮素利用效率、植物产量与品质形成、抗逆性及适应性等方面的研究进展进行了综述。     

Isolation, characterization and transposition of an (IS2)2 intermediate

We have isolated and characterized a dimer derivative of the extensively studiedEscherichia coli insertion sequence IS2. The dimer structure — called (IS2)₂ — consists of two IS2 elements arranged as a direct repeat, separated by 1 bp. The junction between the (IS2)₂ dimer and target sequences is located at various positions in independent isolates; however, one position was preferred. The transposition of (IS2)₂ into a target plasmid resulted in cointegrate-type structures. The transposition frequency of the (IS2)₂ dimer itself was significantly higher than that of the isogenic monomer IS2 insertion. The poor stability and high activity of (IS2)₂ indicates that this is an active transposition intermediate. The mode of transposition of (IS2)₂ is analogous to the joined dimer model described in the case of (IS21)₂ and (IS30)₂.     

Effects of CO2 elevation on canopy development in the stands of two co-occurring annuals

Elevated CO₂ may increase dry mass production of canopies directly through increasing net assimilation rate of leaves and also indirectly through increasing leaf area index (LAI). We studied the effects of CO₂ elevation on canopy productivity and development in monospecific and mixed (1:1) stands of two co-occurring C₃ annual species, Abutilon theophrasti, and Ambrosia artemisiifolia. The stands were established in the glasshouse with two CO₂ levels (360 and 700 l/l) under natural light conditions. The planting density was 100 per m² and LAI increased up to 2.6 in 53 days of growth. Root competition was excluded by growing each plant in an individual pot. However, interference was apparent in the amount of photons absorbed by the plants and in photon absorption per unit leaf area. Greater photon absorption by Abutilon in the mixed stand was due to different canopy structures: Abutilon distributed leaves in the upper layers in the canopy while Ambrosia distributed leaves more to the lower layers. CO₂ elevation did not affect the relative performance and light interception of the two species in mixed stands. Total aboveground dry mass was significantly increased with CO₂ elevation, while no significant effects on leaf area development were observed. CO₂ elevation increased dry mass production by 30–50%, which was mediated by 35–38% increase in the net assimilation rate (NAR) and 37–60% increase in the nitrogen use efficiency (NUE, net assimilation rate per unit leaf nitrogen). Since there was a strong overall correlation between LAI and aboveground nitrogen and no significant difference was found in the regression of LAI against aboveground nitrogen between the two CO₂ levels, we hypothesized that leaf area development was controlled by the amount of nitrogen taken up from the soil. This hypothesis suggests that the increased LAI with CO₂ elevation observed by several authors might be due to increased uptake of nitrogen with increased root growth.     

Symbiotic N2-fixation in alpine tundra: ecosystem input and variation in fixation rates among communities

Annual inputs of symbiotic N₂-fixation associated with 3 species of alpine Trifolium were estimated in four alpine communities differing in resource supplies. We hypothesized that fixation rates would vary according to the degree of N, P, and water limitation of production, with the higher rates of fixation in N limited communities (dry meadow, moist meadow) and lower rates in P and water limited communities (wet meadow, fellfield). To estimate N₂-fixation rates, natural abundance of N isotopes (¹⁵N) were measured in field collected Trifolium and reference plants and in Trifolium plants grown in N-free medium in a growth chamber. All three Trifolium species relied on a large proportion of atmospherically-fixed N₂ to meet their N requirements, ranging from 70 to 100%. There were no apparent differences in the proportion of plant N derived from fixation among the communities, but differences in the contribution of the Trifolium species to community cover resulted in a wide range of annual N inputs from fixation, from 127 mg m^–2 year^–1 in wet meadows to 810 mg m^–2 year^–1 in fellfields. Annual spatially integrated input of symbiotic N₂-fixation to Niwot Ridge, Colorado was estimated at 490 mg m^–2 year^–1 (5 kg ha^–1 year^–1), which is relatively high in the context of estimates of net N mineralization and N deposition.     

Contrasting patterns of photosynthetic acclimation and photoinhibition in two evergreen herbs from a winter deciduous forest

The relationship between the microclimate within an Oak-Hickory forest and photosynthetic characters of two resident evergreen herbs with contrasting leaf phenologies was investigated on a monthly basis for 1 full year. Heuchera americana has leaf flushes in the spring and fall, with average leaf life spans of 6–7 months. Hexastylis arifolia produces a single cohort of leaves each spring with a leaf life span of 12–13 months. We predicted that among evergreen plants inhabiting a seasonal habitat, a species for which the frequency of leaf turnover is greater than the frequency of seasonal extremes would have a greater annual range in photosynthetic capacity than a species that only produced a single flush of leaves during the year. Photosynthetic parameters, including apparent quantum yield, maximum photosynthetic capacity (P_max), temperature of maximum photosynthesis, photochemical efficiency of PSII and leaf nitrogen (N) and chlorophyll concentrations, were periodically measured under laboratory conditions in leaves sampled from natural populations of both species. Mature leaves of both species acclimated to changing understory conditions with the mean seasonal differences being significantly greater for Heuchera than for Hexastylis. Area based maximum photosynthetic rates at 25°C were approximately 250% and 100% greater in winter leaves than summer leaves for Heuchera and Hexastylis respectively. Nitrogen concentrations were highest in winter leaves. Chlorophyll concentrations were highest in summer leaves. Low P_max/N values for these species suggest preferential allocation of leaf nitrogen into non-photosynthetic pools and/or light-harvesting function at the expense of photosynthetic enzymes and electron transport components. Despite the increase in photosynthetic capacity, there was evidence of chronic winter photoinhibition in Hexastylis, but not in Heuchera. Among these ecologically similar species, there appears to be a trade-off between the frequency of leaf production and the balance of photosynthetic acclimation and photoinhibition.     

Regulation of nitrate assimilation in the cyanobacterium Phormidium laminosum

The intracellular ratio of 2-oxoglutarate to glutamine has been analyzed under nutritional conditions leading to different activity levels of nitrate-assimilating enzymes in Phormidium laminosum (Agardh) Gom. This non-N₂-fixing cyanobacterium adapted to the available nitrogen source by modifying its nitrate reductase (NR; EC 1.7.7.2), nitrite reductase (NiR; EC 1.7.7.1) and glutamine synthetase (GS; EC 6.3.1.2) activities. The 2-oxoglutarate/glutamine ratio was similar in cells adapted to grow with nitrate or ammonium. However, metabolic conditions that increased this ratio [i.e., nitrogen starvation or l-methionine-d,l-sulfoximine (MSX) treatment] corresponded to high activity levels of NR, NiR, GS (except in MSX-treated cells) and glutamate synthase (GOGAT; EC 1.4.7.1). By contrast, metabolic conditions that diminished this ratio (i.e., addition of ammonium to nitrate-growing cells or addition of nitrate or ammonium to nitrogen-starved cells) resulted in low activity levels. The variation in the 2-oxoglutarate/glutamine ratio preceded the changes in enzyme activities. These results suggest that changes in the 2-oxoglutarate/glutamine ratio could be the signal that triggers the adaptation of P. laminosum cells to variations in the available nitrogen source, as occurs in enterobacteria.Abbreviations Chl chlorophyll - GOGAT ferredoxin-dependent glutamate synthase (EC 1.4.7.1) - GS glutamine synthetase (EC 6.3.1.2) - MSX l-methionine-d,l-sulfoximine - NiR nitrite reductase (EC 1.7.7.1) - NR nitrate reductase (EC 1.7.7.2) - TP total protein This work has been partially supported by grants from the Spanish Ministry of Education and Science (DGICYT PB88-0300 and PB92-0464) and the University of the Basque Country (042.310-EC203/94). M.I.T. was the recipient of a fellowship from the Basque Government.     

Study of nonculturable Legionella pneumophila cells during multiple-nutrient starvation

Abstract: The nonculturable form of Legionella pneumophila in multiple-nutrient starvation culture was studied. During extended starvation, the total direct counts (TDC) of L. pneumophila did not change significantly, but no colonies were detected on day 50. Quantitative PCR detection of L. pneumophila DNA demonstrated that nonculturable cells retained PCR-detectable DNA even after starvation for 300 days, and part of the nonculturable population possessed nonspecific esterase activity. However, resuscitation trials of nonculturable L. pneumophila on day 100 of starvation recovered no colony-forming units, and electrophoresis of nucleic acids extracted from nonculturable cells revealed rRNA subunit (23S, 16S and 5S) degradation. When legionellae have lost the ability to multiply, at least some DNA and enzyme functions may be retained for prolonged periods.