Evolution in Spartina (Gramineae) IV. The cytology of S. alterniflora Loisel. in North America

A cytological survey of Spartina alterniflora Loisel. populations in Canada and north-eastern U.S.A. establishes the widespread and seemingly exclusive occurrence of the 2 n = 62 chromosome number in that region. The data indicate that the introduced and relict populations of S. alterniflora in Southampton Water, Britain (whence arose S. × townsendii ) are not cyto-logically atypical of the main body of this species in North America, and there is therefore no reason to doubt, on the grounds of aberrant chromosome number, the role of S. alterniflora as a parent of S. × townsendii.
2 n = 62 is anomalous with respect to the basic number of x = 10 generally found in the genus. The present results indicate that 2 n = 62 is widespread in north-eastern North American S. alterniflora , and no other chromosome number has been found in a survey of the region. But the species is wide-ranging and the possibility of 2 n = 60 occurring in other areas, especially in the south of its range, cannot be ruled out. However, the only chromosome number so far confirmed in southern populations is a count of 2 n = 62 from Texas.     

Populations of Anaerobic Phototrophic Bacteria in a Spartina alterniflora Salt Marsh

Habitat-simulating media were used with the Hungate anaerobic roll tube technique to enumerate culturable anaerobic photosynthetic bacteria in sediment, tidal waters, and Spartina alterniflora plant samples collected from the salt marsh at Sapelo Island, Ga. No phototrophs were detected in samples of creekside (low marsh) sediment or in tidal waters in creekside regions. In the high marsh region, 90% of anaerobic phototrophic bacteria occurred in the top 5 mm of sediment and none were detected below 6 mm. There was a seasonal variation, with maximal populations occurring in summer and fall (mean, 4.4 × 10⁵ phototrophs g of dry sediment⁻¹) and minimal numbers occurring in winter (mean, 3.9 × 10³ phototrophs g of dry sediment⁻¹). During winter and late spring, phototrophs had a patchy distribution over the high marsh sediment surface. In contrast, during late summer they had a random uniform distribution. Tidal water collected over high marsh sediment contained an average of 8.7 × 10² phototrophs ml⁻¹, with no significant seasonal variation. Anaerobic phototrophic bacteria were also cultured from the lower stem tissue of S. alterniflora growing in both the high (4.3 × 10⁴ phototrophs g of dry tissue⁻¹) and creekside (4.9 × 10⁴ phototrophs g of dry tissue⁻¹) marsh regions. Chromatium buderi, Chromatium vinosum, Thiospirillum sanguineum, Rhodospirillum molischianum, and Chlorobium phaeobacteroides were the predominant anaerobic phototrophic species cultured from high marsh sediment. The two Chromatium species were dominant.     

Effect of Salt Stress on Seed Germination and EmbryoGrowth of Spartina alterniflora (Gramineae)

In this paper , the effect of NaCl concentration ( 1× 104 - 6× 104 mg/L) on the seed germination of smooth cordgrass ( Spartina alterniflora) was investigated using 1/2 Hoagland as the basic culture solution. The results indicated that the coleoptile and embryonal axis grew before the radicle and plumule in the stage of germination . Salinity level had no influence on the seed germination percentage when the salt concentration didn′t exceed 3×104 mg/L. The optimal salinity level for seed germination and embryo growth was 1×104 mg/L . The inhibit effect of salt concentration on the growth of embryo′s different part was different, and the length of radicle and plumule decreased significantly with the increase of salt concentration. However , the lesser inhibition on the embryonal axis and coleoptile was observed under the higher salt concentration, and thus the seedlings out of soil were ensured and the species was quickly adapted to the environment of inter- tidal zone .     

盐胁迫对互花米草种子萌发及胚生长的影响

以1/2Hoagland溶液为基础培养液,研究了1×104-6×104mg/L NaCl对互花米草(Spartina alterniflora)种子萌发的影响.结果表明,互花米草种子在萌发阶段胚芽鞘和胚轴生长先于胚根和胚芽;当盐浓度不超过3×104mg/L时,互花米草种子的萌发率未受到影响,种子萌发及胚生长的适宜盐浓度为1 x104mg/L,盐浓度对胚的不同部位生长的抑制程度不同,随着盐浓度的升高,胚根、胚芽的长度旱明显下降趋势,但盐浓度对胚轴、胚芽鞘生长的抑制作用较小,有利于已萌发的互花米草幼苗快速出土,迅速适应多变的潮间带环境.     

Osmotic potential and turgor maintenance in Spartina alterniflora Loisel.

Summary The dependence of leaf water potential (), osmotic potential () and turgor pressure (P) on relative water content (RWC) was determined for leaves of tall and short growth forms of Spartina alterniflora Loisel. from a site on Canary Creek marsh in Lewes, Delaware. Tall plants (ca. 1.5 m) occured along a drainage ditch where interstitial water salinity was approximately 20, and short plants (ca. 0.2 m) were 13 m away near a pan and exposed to 80 salinity during the most stressful period. Leaves were collected at dawn and pressure-volume measurements were made as they desiccated in the laboratory. Pressure equilibrium was used to measure , RWC was determined from weight loss and dry weight, was determined from the pressure volume curve, and P was calculated as the difference between and . Physical properties of the bulk leaf tissue that have a role in regulating water balance of the two growth forms were estimated: relative water content of apoplastic water (RWC_a) relative water content at zero turgor (RWC₀), the bulk modulus of elasticity (E), and water capacity (C _w). There were no detectable temporal trends in any of the parameters measured from Nune through September and no significant differences between the two growth forms when compared on the basis of RWC_a, RWC₀, E, and C _w. There was a clear difference between the two growth forms with respect to ; at RWC₀, was-4.5±0.40 MPa for short form plants and-3.3±0.40 MPa for tall form.Turgor pressure of plants in the field (P) was lower in leaves from short form than for the tall form plants with average difference of about 0.4 MPa. In July, P in short form leaves dropped to zero by mid-morning as expected for leaves experiencing water stress.These results show that S. alterniflora is capable of reducing osmotic potential in response to increased salinity and that turgor pressure was lower in short growth form than in tall forms.     

互花米草生物质能利用潜力

作为外来种,互花米草(Spartina alterniflora)对入侵地的生态系统产生了较强的干扰,但同时高生物量的互花米草也是一种潜在的生物质能源.发展生物质能是充分利用互花米草资源并控制其恶性扩张的较为有效和实用的途径,具有生态和经济双重效益.本文总结了互花米草生物质能的利用潜力,其表现为时间与空间上的生物量资源优势、高效的光合作用机制与高生产力、高贮能、较高的碳水化合物、蛋白质和脂肪储量以及不占用耕地等;同时介绍了互花米草生物质能开发利用现状,并指出互花米草生物质能的开发与利用有着光明的前景.     

天津滨海滩涂互花米草有性繁殖特性

对分布在天津滨海滩涂的互花米草（Spartina alterniflora Loisel．）在开花、授粉、结实等方面进行了研究,结果表明：互花米草花期从8月中旬开始至10月下旬结束,花粉／胚珠（P／O）值为9874．67±2149．39,花粉粒小,适于风媒传粉;花粉活力随着散粉时间的延长呈指数递减,柱头具有适于捕捉花粉的特性,体外花粉管的生长表明,花粉的萌发能力较强;平均结实率为（67．56±2．39）％,种子萌发率高于80％,种子繁殖为种群的拓殖及补充起到重要作用。     

外来物种互花米草种子萌发的生态适应性

在3种条件即不同萌发温度和光照、不同贮藏温度和时间、不同盐浓度下,研究了互花米草种子萌发及胚生长特性.结果表明:在相同温度下,种子的萌发不受光照或黑暗条件影响,最适萌发温度为16/26℃(夜/昼)和25℃,萌发率高于90%;在-5℃、0℃、5℃、10℃的贮藏温度下,贮藏120 d的种子萌发率高于74%,表明种子能够安全越冬;当盐浓度为75～225 mmol·L~(-1)时,萌发率高于90%,150 mmol·L~(-1)的盐浓度较适宜胚的生长,胚芽鞘和胚轴的生长先于胚芽和胚根,盐溶液对胚轴、胚芽鞘的生长所产生的抑制作用小于胚根、胚芽,有利于已萌发的幼苗快速出土,适应多变的潮间带环境.     

Comparison of Nitrogen Fixation Activity in Tall and Short Spartina alterniflora Salt Marsh Soils

A comparison of the N₂ fixers in the tall Spartina alterniflora and short S. alterniflora marsh soils was investigated. Zero-order kinetics and first-order kinetics of acetylene reduction were used to describe the activity of the N₂ fixers in marsh soil slurries. It was found that the V_max values were approximately 10 times greater for the N₂ fixers in the tall Spartina than in the short Spartina marsh when raffinose was used as the energy source. In addition, the (K_s + S_n) values were approximately 4 to 15 times lower for the N₂ fixers in the tall Spartina than in short Spartina marsh. First-order kinetics of nitrogen fixation for several substrates indicate that the N₂ fixers in the tall Spartina marsh were two to seven times more active than those in the short Spartina marsh. Ammonium chloride (25 μg/ml) did not inhibit nitrogen fixation in the tall Spartina marsh, but there was a 50% inhibition in nitrogen fixation in the short Spartina marsh. On the other hand, sodium nitrate inhibited nitrogen fixation almost 100% at 25 μg/ml in both soil environments. Amino nitrogen (25 to 100 μg/ml) had little or no effect on nitrogen fixation. The results indicate that the N₂ fixers in the tall Spartina marsh were physiologically more responsive to nutrient addition than those in the short Spartina marsh. This difference in the two populations may be related to the difference in daily tidal influence in the respective areas and thus provide another explanation for the enhanced S. alterniflora production in the creek bank soil system.     

互花米草黄酮含量分析及其生态学意义

互花米草原产于北美洲大西洋沿岸和墨西哥海湾,经引种和其他原因,已扩散到包括中国在内的多个国家和地区,并对被入侵地生态系统的结构和功能均造成了显著影响。有关该物种的入侵机制和控制策略是当前入侵生态学研究领域的热点。互花米草生物质材料中富含黄酮类物质,与该物种向海扩张的能力可能存在一定联系。鉴于黄酮广泛的应用价值,能否借助黄酮成分的开发带动生物质的收割,以达到有效控制该物种的目的,也是当前研究者所关注的问题。以芦丁为标准参照物,NaNO2-Al（ NO3）3法比较温室互花米草不同器官中总黄酮含量的差异,分析盐城滩涂互花米草越冬芽黄酮含量与所在地理位置之间的关系,采用L9（34）正交试验对干储互花米草叶总黄酮的提取工艺进行优化。互花米草叶片中黄酮类物质远高于根、根状茎、茎、叶鞘、颖稃及种子。盐城滩涂上互花米草越冬芽的黄酮含量随着由陆向海方向基本呈升高趋势。互花米草总黄酮最佳提取工艺为料液比1∶30,乙醇浓度70％,水浴温度80℃,水浴时间2h。互花米草植物材料中,尤其在叶部,黄酮含量十分丰富。该黄酮物质与互花米草在海岸带盐沼生态系统中的适应和向海扩张也存在正相关关系,可作为探索互花米草入侵机制的一个方向。利用本研究中所得优化提取工艺可从互花米草干储生物质中获得稳定的黄酮来源。配合黄酮经济成分的开发而推动生物质材料的收割利用,将成为互花米草生态控制的一项潜在策略。     

Effect of the Spartina alterniflora Root-Rhizome System on Salt Marsh Soil Denitrifying Bacteria

Nitrous oxide (N₂O) reductase activity was used as an index of the denitrification potential in salt marsh soils. In a short Spartina alterniflora marsh, the seasonal distribution of N₂O reductase activity indicated a causal relationship between S. alterniflora root-rhizome production and the denitrification potential of the soil system. The relationship was not discerned in samples from a tall S. alterniflora marsh. To further examine the in situ plant-denitrifier interaction in the short S. alterniflora marsh, plots with and without living S. alterniflora were established and analyzed for N₂O reductase activity 5 and 18 months later. In the plots without living Spartina there was a significant reduction in the soil denitrification potential after 18 months, indicating that in the SS marsh the denitrifiers are tightly coupled to the seasonal production of below-ground Spartina macroorganic matter. In plots with intact Spartina, the soil denitrification potential was not altered by NH₄NO₃ or glucose enrichment. However, in plots without living Spartina, there were significant changes in soil N₂O reductase activity, thus indicating that the plants can serve as a “buffer” against this form of pulse perturbation.     

Endorhizal and Exorhizal Acetylene-reducing Activity in a Grass (Spartina alterniflora Loisel.)-Diazotroph Association

Earlier studies indicated that bacteria responsible for nitrogenase activity of some grasses are located inside the roots. Those studies were conducted with excised roots in which a long, unexplained “lag phase” occurred before initiation of nitrogenase activity. When hydroponically maintained Spartina alterniflora Loisel. was incubated in a two-compartment system with acetylene, ethylene was produced following, at most, a 2-hour lag in both the upper (shoot) and lower (roots + water) phases. Ethylene production in the upper phase not attributable to leaf-associated acetylene-reducing activity or to diffusion of ethylene from around the roots is considered to represent “endorhizal acetylene-reducing activity,” the internally produced ethylene diffusing into the upper phase via the lacunae. Ethylene produced in the lower phase is designated “exorhizal acetylene-reducing activity.” The endorhizal acetylene-reducing activity, in comparison to exorhizal activity, was relatively insensitive to additions of HgCl₂, NH₄Cl, or carbon sources to the lower phase. Post-lag acetylene-reducing activity of roots excised from plants growing in soil responded to additions in a manner similar to that of endorhizal acetylene-reducing activity, whereas post-lag acetylene-reducing activity of rhizosphere soil responded in a manner similar to that of exorhizal acetylene-reducing activity.     

沼泽湿地互花米草植物体传输与排放甲烷特征

于各测定月的小潮日,使用悬管装置采集气样并结合气相色谱测定,对闽江河口互花米草（Spartina alterniflora）沼泽湿地互花米草植株的甲烷传输量及其主要释放部位进行了研究,另又采用静态箱法-气相色谱法测定了互花米草沼泽湿地甲烷的排放通量,以此分析互花米草植物体甲烷传输对互花米草沼泽湿地甲烷排放通量的贡献率,最后测定了互花米草植株髓腔内的甲烷浓度。结果表明,不同生长阶段的互花米草植株甲烷传输量明显不同,快速生长阶段的互花米草植株甲烷传输量最高;互花米草植株甲烷传输对互花米草沼泽湿地甲烷排放通量的贡献率介于9%-94%之间;互花米草植物体传输甲烷的主要释放部位是距地面0-20cm处,该部位对植物甲烷传输量的贡献率为50%（平均值）;髓腔内的甲烷浓度远高于大气中的甲烷浓度,且自下而上呈递减趋势。     

Relative Importance of Ion Exclusion, Secretion and Accumulation in Spartina alterniflora Loisel.

The extent to which Spartina alterniflora Loisel. excluded,secreted or accumulated the major seawater ions (Cl^-, SO^2-₄,Na⁺, K⁺, Mg²⁺, and Ca²⁺) was investigated under varying salinitytreatments. From a quantitative viewpoint, ion exclusion wasmost prominent and accounted for 91–97% of the theoreticalmaximum ion uptake as a result of transpiration and growth.Of those ions taken up, approximately half was secreted fromthe shoots. Relative to K⁺, a disproportionate amount of Na⁺was excluded at the roots and secreted by the shoots. The concentrationwithin the tissues of S. alterniflora did not change with salinitytreatment for the majority of the ions examined, but Na⁺ wasmore than twice as concentrated at 40 g dm^-3 than at lOgdm^-3.Calculations of the flux of ions from salt marsh sediments tothe flood water via shoot secretion or stem/leaf turnover indicatethat these processes may be important to the ecology of S. alternifloraas mechanisms that limit the accumulation of salt within theroot zone.     

Changes in Ecosystem Nitrogen and Carbon Allocation with Black Mangrove (Avicennia germinans) Encroachment into Spartina alterniflora Salt Marsh

Ecosystems - Increases in temperature are expected to facilitate encroachment of tropical mangrove forests into temperate salt marshes, yet the effects on ecosystem services are understudied. Our...     

三种类型互花米草抗盐生态型的分化

从美国引种成功的三种类型互花米草在不同NaCl浓度的盐渍生境中,叶细胞膜透性、渗透调节物(主要是K+、Na+)和氨基酸的变化以及光合作用、呼吸作用的变化都存在明显的差异,这是由于长期不同生境的选择和互花米草的基因型适应所造成的生态型分化的结果。按抗盐性分：G型抗性最强、F型最弱、N型居中。     

Enumeration and Localization of N(2)-Fixing Bacteria Associated with Roots of Spartina alterniflora Loisel

Numbers and possible locations of N(2)-fixing bacteria were investigated in roots of Spartina alterniflora Loisel, which support nitrogenase activity in the undisturbed native habitat. N(2)-fixing bacteria were recovered in cultures both from S. alterniflora roots and from the surrounding sediment, and they formed a greater proportion of the bacteria recovered from root homogenates than from salt-marsh sediment. N(2)-fixing bacteria were recovered in high numbers from the rhizoplane of S. alterniflora after roots were treated with 1 or 5% chloramine-T for 1 h or with 1% NaOCl for 1 or 2 h. Immersing S. alterniflora roots in 5% NaOCl for 1 h was more effective in distinguishing bacteria inside the roots since this treatment nearly eliminated N(2)-fixing bacteria recoverable from the rhizoplane, although high numbers of N(2)-fixing bacteria were recovered from homogenates of roots treated with 5% NaOCl for 1 h. However, this treatment was less effective with roots of Zea mays L. (Funks G4646) and Sorghum bicolor (L.) Moench (CK-60 A), indicating that techniques to surface sterilize roots should be evaluated for different plants. Bacteria were observed by light and electron microscopy inter- and intracellularly in the cortex and in the aerenchyma of S. alterniflora roots. This study clearly shows that bacteria, including N(2) fixers, colonize the interior of roots of S. alterniflora growing in a Chesapeake Bay, Maryland, salt marsh.     

Microdiversity of Culturable Diazotrophs from the Rhizoplanes of the Salt Marsh Grasses Spartina alterniflora and Juncus roemerianus

Abstract Salt marshes dominated by Spartina alterniflora (smooth cordgrass) are among the most productive ecosystems known, despite nitrogen limitation. Rhizoplane/rhizosphere diazotrophy (nitrogen fixation) serves as a significant source of combined nitrogen in these systems. Several recent studies have demonstrated remarkable physiological and phylogenetic macro- and microdiversity within this important functional group of organisms. However, the ecological significance of this diversity is presently unknown. The physiological characteristics of the culturable, oxygen-utilizing fraction of the rhizoplane diazotroph assemblages from Spartina alterniflora and from another salt marsh grass, the black needle rush Juncus roemerianus, were examined in combination with an assessment of the phylogenetic relatedness by whole genome DNA–DNA hybridization. Analysis of substrate utilization data permitted quantitative evaluation of fully cross-hybridizing strain groups and physiological clusters. Phylogenetically related strains, defined by DNA homology ≥90% relative to the positive control, displayed extensive physiological diversity. Seven bootstrap-supported physiological clusters, composed largely of phylogenetically dissimilar strains, showed similar utilization patterns for at least one class of ecologically relevant substrates (carbohydrates, carboxylic acids, or amino acids). These diazotrophs appear to be physiologically adapted for utilization of specific substrates or classes of substrates, lending support to diazotrophic functional redundancy. Microenvironmental heterogeneity is credited for promoting this diversity by selecting for physiologically specialized diazotroph populations to occupy defined niches in situ. One outcome of this physiological diversity is maintenance of a crucial environmental function (nitrogen fixation) over a broad range of environmental conditions. Received: 15 October 1999; Accepted: 28 December 1999; Online Publication: 25 April 2000     

Role of the Salt Marsh Grass Spartina alterniflora in the Response of Soil-Denitrifying Bacteria to Glucose Enrichment

Long-term incubations of salt marsh soil systems in the presence of glucose resulted in a decrease in the soils' denitrification potential. Addition of nitrate or the presence of living Spartina alterniflora reversed this effect, indicating that Spartina, through the establishment of an oxidized rhizosphere where nitrification can occur, enables the denitrifying bacteria to adequately compete with the less energetically efficient components of the anaerobic soil microbial community.