长白山哈泥泥炭地丘间生境泥炭藓孢子的寿命

长寿有性繁殖体对于植物种群的长存具有重要意义,迄今,泥炭地苔藓植物孢子长寿性研究还很少。在长白山哈泥泥炭地钻取丘间表层泥炭样品,测定泥炭腐殖化度和烧失量,逐层提取和培养泥炭藓孢子,研究埋藏时间对孢子萌发的影响。结果表明,丘间泥炭藓孢子埋藏环境中,随着埋深的增加即埋藏年限的增加,泥炭腐殖化度和烧失量总体上分别呈现增加和递减的趋势,而地层泥炭藓孢子萌发率呈现直线递减的规律,但在埋藏近150余年后孢子萌发率仍可达40%。研究进一步证明泥炭藓具有长期持久孢子库,根据推算,泥炭地丘间埋藏环境中,泥炭藓孢子最大寿命可超过400a。     

火烧高温对泥炭藓孢子萌发力影响的模拟实验

作为生态系统稳定性维持的一个重要因素,火对泥炭地优势植物泥炭藓(Sphagnum)孢子库的影响尚不清楚.以采自长白山区泥炭地的泥炭土和3种泥炭藓的成熟孢子为实验材料,室内模拟火烧,以此设置不同温度水平(20、40、60或100℃,持续0.5、1、2、4或10 min),对泥炭藓孢子进行热激处理,经萌发实验后,研究火烧高温对孢子萌发率的影响.结果显示,火烧期间各层土温随深度而递减,表层泥炭可达300℃的极端高温,而1 cm深温度仅为70℃,体现出泥炭土良好的热缓冲性;40℃的热激可使锈色泥炭藓(S.fuscum)与中位泥炭藓(S.magellanicum)孢子萌发率提高20%与50%;60℃的热激使尖叶泥炭藓(S.capillifolium)孢子的萌发率提高1倍;100℃热激对3种泥炭藓孢子萌发则有强烈的抑制作用.研究表明,泥炭藓孢子耐受高温的能力有限,但土壤中的孢子凭借泥炭的良好热缓冲性,可以躲避火烧高温造成的致命伤害,适度的热激甚至能提高其萌发力,对其在火后的建植及种群的长存可能有重要意义.     

泥炭地苔藓植物孢子生活力的快速检测

适量的烟气能够促进有性繁殖体萌发,但迄今尚无辅助烟气处理探究孢子生活力快速检测方法的研究报道。该文选择毛缘泥炭藓（Sphagnum fimbriatum）、中位泥炭藓（S.magellanicum）和粗叶泥炭藓（S.squarrosum）作为材料,分别使用亚甲基蓝染色法、四唑（TTC）染色法、碘-碘化钾（I₂-KI）染色法和红墨水染色法对泥炭藓孢子进行染色,并比照营养液、烟溶液+营养液培养的孢子萌发试验,对比研究泥炭地苔藓植物孢子生活力快速检测的最佳方法。结果表明：亚甲基蓝染色法的染色效果最为明显,TTC和I₂-KI均未能使泥炭藓孢子着色,孢子对红墨水虽有着色反应但不清晰;与营养液培养相比,添加烟溶液使毛缘泥炭藓、中位泥炭藓和粗叶泥炭藓孢子萌发率分别提高5%、5%和18%;使用亚甲基蓝染色的孢子染色率与经烟溶液处理过的孢子萌发率最为接近。综上认为,亚甲基蓝染色法能快速检测泥炭藓孢子的生活力。     

烟气对泥炭藓孢子萌发影响的模拟研究

适量烟气能促进种子萌发,但对苔藓植物孢子的作用尚不清楚.选取采自长白山区泥炭地的粗叶泥炭藓和中位泥炭藓的孢蒴为试验材料,通过燃烧泥炭地植物产生烟气,制备烟溶液,分别与不同大小(大:直径为2.10～2.50 mm;小:直径为1.50～1.90 mm)以及不同保存时长(旧:4.3和6.3年;新:0.3年)的孢蒴进行两组双因素试验,经不同时长的烟溶液浸泡和萌发试验,模拟研究烟气、孢蒴大小和保存时长对苔藓植物孢子萌发的影响.结果表明: 烟溶液浸泡影响孢子萌发,培养10 d时,不同时长的烟溶液浸泡均可使孢子的萌发率提高5倍以上,小孢蒴孢子的萌发率高;培养21 d时,仅适度浸泡(3 d)表现出促进萌发的作用,孢蒴大小对孢子萌发率无影响;烟溶液浸泡对长时间保存(4.3和6.3年)的孢蒴孢子萌发无促进作用.研究表明,适量烟气可加速新泥炭藓孢子以及小孢蒴孢子的萌发.在存在不定期火烧干扰的泥炭地中,与对种子植物的作用类似,烟气可能在苔藓植物种群的有性更新和种群维持中发挥重要作用.     

泥炭地特征性环境因子促进泥炭藓持久孢子库的形成

研究泥炭地特征性环境因子——淹水、少氧和化感物质对泥炭藓孢子持久性的影响, 可深入理解泥炭地泥炭藓持久孢子库的形成机制, 为退化泥炭地泥炭藓地被恢复研究提供参考。该研究以藓丘种和丘间种两种泥炭藓的孢子为试验材料, 通过室内模拟控制实验的方法, 研究泥炭藓孢子在空气、超纯水、泥炭地地表水和泥炭藓沥出液中, 及3种速率充气下, 孢子萌发力持久性的变化。经充气处理后, 泥炭藓孢子持久性显著低于不充气处理。不充气时, 泥炭藓孢子在含有化感物质的泥炭地地表水和泥炭藓沥出液中保存, 持久性显著高于在超纯水中保存。通径分析结果显示, 溶解氧是影响泥炭地泥炭藓孢子持久性的主要因子和限制因子, 养分元素氮(TN)和磷(TP)的浓度为孢子持久性的负作用因子。研究结果表明, 泥炭藓孢子散布于苔藓地被基质或淹水的丘间生境中, 比暴露于空气或在无化感物质的水中, 能更好地维持萌发力。泥炭地中, 泥炭藓孢子和其他植物的繁殖体的超长寿命可能归因于少氧、养分贫乏和丰富的化感物质等泥炭地特征性环境因子。     

泥炭地特征性环境因子促进泥炭藓持久孢子库的形成

研究泥炭地特征性环境因子——淹水、少氧和化感物质对泥炭藓孢子持久性的影响,可深入理解泥炭地泥炭藓持久孢子库的形成机制,为退化泥炭地泥炭藓地被恢复研究提供参考。该研究以藓丘种和丘间种两种泥炭藓的孢子为试验材料,通过室内模拟控制实验的方法,研究泥炭藓孢子在空气、超纯水、泥炭地地表水和泥炭藓沥出液中,及3种速率充气下,孢子萌发力持久性的变化。经充气处理后,泥炭藓孢子持久性显著低于不充气处理。不充气时,泥炭藓孢子在含有化感物质的泥炭地地表水和泥炭藓沥出液中保存,持久性显著高于在超纯水中保存。通径分析结果显示,溶解氧是影响泥炭地泥炭藓孢子持久性的主要因子和限制因子,养分元素氮(TN)和磷(TP)的浓度为孢子持久性的负作用因子。研究结果表明,泥炭藓孢子散布于苔藓地被基质或淹水的丘间生境中,比暴露于空气或在无化感物质的水中,能更好地维持萌发力。泥炭地中,泥炭藓孢子和其他植物的繁殖体的超长寿命可能归因于少氧、养分贫乏和丰富的化感物质等泥炭地特征性环境因子。     

白江河泥炭地泥炭藓孢子萌发力对排水的响应

排水严重改变泥炭地的环境和生态过程,但对泥炭藓孢子萌发力的影响尚不清楚。在长白山地区白江河泥炭地,分别在优势植物为苔藓的近原始地段和优势植物为小灌木的排水地段,钻取泥炭柱芯为试验材料,逐层测试泥炭理化指标,提取泥炭藓孢子并进行萌发试验,统计孢子数量和萌发力;经过泥炭样品年代测定,建立深度年代关系曲线,研究泥炭藓孢子萌发力对排水的响应和机制。结果表明: 整个柱芯对比,近原始地段平均孢子数略高于排水地段,两地段的平均孢子萌发力无差异,排水地段的泥炭容重、总碳和总氮都显著高于近原始地段。柱芯上部对比,排水(1987年)以后两地段孢子累积速率无显著差异,但近原始地段的平均孢子萌发力(34%)远低于排水地段(72%)。近原始地段的碳氮比与孢子萌发力呈显著正相关;排水地段的总碳、pH和埋藏时间与孢子萌发力呈显著负相关。30年前的泥炭地排水虽对孢子累积影响不大,但通过加速分解而改变了泥炭的理化性质,提升了表层泥炭中孢子萌发力,因此降低孢子库的持久性,可能导致泥炭藓在灾变性干扰后的种群持续更新潜力下降。     

四种苔藓植物提取液对二种蓼科植物种子萌发和幼苗生长的影响

研究卵叶泥炭藓(Sphagnumovatum),卷叶凤尾藓(Fissidenscristatus),弯叶灰藓(Hypnumcallichroum)和大金发藓(Polytrichumcommune)的水粗提取液对维管植物虎杖和皱叶酸模种子萌发和幼苗生长的影响。结果显示:四种苔藓植物的粗提取液对两种植物的种子萌发率并没有显著影响。然而,弯叶灰藓,、卵叶泥炭藓和卷叶凤尾藓的提取液抑制了皱叶酸模种子的活力指数。除此之外,卷叶凤尾藓还显著地抑制了它幼苗的干重。四种藓类的提取液对虎杖的种子活力指数和干重,但是卷叶凤尾藓的提取液对幼苗的生长有显著的影响。苔藓植物粗提取液对种子萌发和幼苗生长的影响的机制并不清楚,有待进一步研究。     

养分浓度和光照强度对泥炭藓有性更新的影响

作为优势植物, 泥炭藓(Sphagnum)在泥炭沼泽中缺乏有性更新的原因尚不清楚。针对影响孢子萌发的光强和养分条件, 以泥炭藓(S. palustre)为材料, 通过室内孢子萌发实验, 研究不同光强和养分浓度对孢子萌发率、萌发势及萌发指数的影响。4 种培养基中, 养分浓度高的营养液培养基中孢子萌发率最高, 达到60%, 其次为养分浓度与营养液相近的琼脂+营养液培养基, 萌发率为48%, 再次为养分水平很低的沼泽水培养基, 萌发率约为30%, 几乎无养分的蒸馏水培养基中萌发率最低, 约为5%。萌发势和萌发指数亦呈现相同的规律。琼脂+营养液和营养液培养基较沼泽水和蒸馏水培养基孢子萌发时间提前约3 天时间。增加光强使孢子萌发率仅提高10%。研究表明, 低养分浓度和弱光照均不利于孢子萌发, 相对而言, 泥炭沼泽的贫营养特征应是限制泥炭藓有性更新的更重要因素。     

长白山哈泥泥炭地七种苔藓植物生态位

采用Levins和Pianka公式,对哈泥泥炭地7种苔藓植物的生态位进行了研究.结果表明：7种苔藓在泥炭的全氮、全磷、Ca²⁺、K⁺、沼泽水的pH和电导率、乔木郁闭度、灌木盖度以及水位埋深9个环境因子梯度上的平均生态位宽度排序为：沼泽皱缩藓＞喙叶泥炭藓＞中位泥炭藓＞尖叶泥炭藓、桧叶金发藓＞大泥炭藓＞锈色泥炭藓.锈色泥炭藓倾向于特化种,沼泽皱缩藓倾向于泛化种.在各种环境因子中,以电导率平均重叠值最高,水位埋深、乔木郁闭度、pH和灌木盖度梯度上平均重叠值最低,是影响苔藓分布的主要环境因子.多数苔藓在这4个梯度上产生生态位分异.少数苔藓种对在所有环境因子梯度重叠值均较高,是由于苔藓之间存在水分协作关系.这为苔藓植物的种间竞争提供了间接证据.     

Experimental evidence for a persistent spore bank in Sphagnum

Spore capsules of four Sphagnum species were buried at different depths in peat on a bog. Spore viability was determined after 0, 1, 2 and 3 yr. Viability generally declined with time, but viable spores were still found at all depths after 3 yr. The light-coloured spores of S. balticum and S. tenellum retained their viability better than the darker spores of S. fuscum and S. lindbergii . Survival was highest under wet but aerobic conditions, but was also high under humid or periodically desiccated conditions. By contrast, most spores stored under wet, anaerobic conditions died within 2–3 yr. These results, and predictions from them, are not consistent with earlier results for spores of long-lived and dominant bryophytes, or for seeds of phanerogams of undisturbed wetlands and forests. There was no correlation between spore size and longevity across species, but the small spores from small capsules of S. balticum and S. tenellum generally showed higher viability than those from the medium-sized and large capsules of the same species. This suggests a positive intraspecific relationship between longevity and dispersal distance. There was an indication of conditional dormancy, controlled by weather, in Sphagnum spores. The experiments indicate that Sphagnum spores can form a long-term persistent spore bank under suitable conditions, with a half-life of between 1 and 20 yr (mean across species of 2.6 and 5.0 yr at two depths studied), and with potential values in individual spore capsules of several decades, or even of centuries. Sphagnum spores kept refrigerated showed 15–35% viable spores after 13 yr. The capacity to form a persistent spore bank that can be activated whenever favourable conditions occur might help explain the wide geographical distribution of many Sphagnum species in the boreal and temperate zones, where they have managed to colonize almost every suitable patch of acidic, nutrient-poor wetland.     

Regeneration of Three <Emphasis Type="Italic">Sphagnum</Emphasis> species

Sphagnum capillifolium var. tenellum, S. magellanicum, and S. recurvum var. brevifolium were regenerated from stem pieces grown in containers to assess their potential for use in peatland restoration projects. The effect of two water levels; peat, peat/sand or peat/clay substrates; and peat decomposition level on the species’ regeneration was evaluated. S. magellanicum attained the greatest cover on the peat or peat/sand mixture using decomposed peat when the growing surface was occasionally inundated. S. recurvum attained the greatest cover grown on the peat or peat/sand mixture using undecomposed peat when the water level was kept below the surface. S. capillifolium showed an affinity for the peat/clay mixture, and overall attained a greater total cover than the other species when grown under the lower water level on all substrate types, with total cover approximately three to five times that of the others. When developing management plans for restoration of mined peatlands, species-specific responses to water level, type and extent of mineral soil mixed with the peat surface, and peat decomposition level should be considered.     

同形鳞毛蕨成精子囊素系统的初步研究

研究了同形鳞毛蕨成精子囊素对该种和水蕨孢子萌发和配子体发育的影响,结果表明：同形鳞毛蕨配子体能产生成精子囊素,该成精子囊素能抑制同种孢子的萌发,抑制作用随配子体成熟度的增加而增强;同形鳞毛蕨成精子囊素还可促进同种孢子发育为雄配子体;光照条件下,同形鳞毛蕨成精子囊素对水蕨孢子萌发和配子体发育影响不大,黑暗条件下,同形鳞毛蕨成精子囊素能显著的促使水蕨孢子提早萌发,但都不影响其孢子最终萌发率和配子体的性别分化,表明同形鳞毛蕨和水蕨的成精子囊素不属于同一系统。     

Interacting effects of elevated atmospheric CO<Subscript>2</Subscript> and hydrology on the growth and carbon sequestration of <Emphasis Type="Italic">Sphagnum</Emphasis> moss

Peatlands are a critical carbon store comprising 30% of the Earth’s terrestrial soil carbon. Sphagnum mosses comprise up to 90% of peat in the northern hemisphere but impacts of climate change on Sphagnum mosses are poorly understood, limiting development of sustainable peatland management and restoration. This study investigates the effects of elevated atmospheric CO₂ (eCO₂) (800 ppm) and hydrology on the growth of Sphagnum fallax, Sphagnum capillifolium and Sphagnum papillosum and greenhouse gas fluxes from moss–peat mesocosms. Elevated CO₂ levels increased Sphagnum height and dry weight but the magnitude of the response differed among species. The most responsive species, S. fallax, yielded the most biomass compared to S. papillosum and S. capillifolium. Water levels and the CO₂ treatment were found to interact, with the highest water level (1 cm below the surface) seeing the largest increase in dry weight under eCO₂ compared to ambient (400 ppm) concentrations. Initially, CO₂ flux rates were similar between CO₂ treatments. After week 9 there was a consistent three-fold increase of the CO₂ sink strength under eCO₂. At the end of the experiment, S. papillosum and S. fallax were greater sinks of CO₂ than S. capillifolium and the ? 7 cm water level treatment showed the strongest CO₂ sink strength. The mesocosms were net sources of CH₄ but the source strength varied with species, specifically S. fallax produced more CH₄ than S. papillosum and S. capillifolium. Our findings demonstrate the importance of species selection on the outcomes of peatland restoration with regards to Sphagnum’s growth and GHG exchange.     

Dry/wet cycling reduces spore germination and viability in six peatland bryophytes

• Dry/wet cycling driven by water level fluctuation in wetlands may strongly influence the destiny of seeds. However, how dry/wet cycling affects spore survival and germinability in peatland bryophytes is poorly understood.
• Six peatland bryophytes, three hummock- and three hollow-dwelling Sphagnum species, were chosen as study species. We tested the effects of dry (60% air RH)/wet (waterlogging) cycle frequency (once per 12, 8 or 4 days for low, medium or high, respectively) and ratio (3:1, 1:1 or 1:3 dry:wet time per cycle) on spore germinability, viability, dormancy percentage and protonema development.
• Dry/wet cycling significantly reduced spore germination percentage and viability and slowed protonema development in all Sphagnum species, being more pronounced with higher dry/wet cycling frequencies. The hummock species S. capillifolium and S. fuscum had higher spore germination percentage after the continuous dry treatment, while the hollow species S. angustifolium, S. squarrosum and S. subsecundum showed the opposite response, compared to the continuously wet treatment. Except for S. squarrosum, spore viability was higher after the dry than after the wet treatment. Spore viability and dormancy percentage were higher after a dry/wet ratio of 1:3 than after ratios of 3:1 and 1:1.
• Our study shows that both germinability and viability of bryophyte spores are reduced by dry/wet cycling (especially when frequent) in peatlands. This emphasizes the need to ensure constant water levels and low frequencies of water level fluctuation, which are relevant in connection with wetland restoration, to promote Sphagnum spore survival and establishment in peatlands after disturbances.

     

Short-term effect of deep shade and enhanced nitrogen supply on Sphagnum capillifolium morphophysiology

Sphagnum capillifolium mesocosms collected from an ombrotrophic blanket bog were subjected to controlled photon flux densities (control and shaded) and nitrogen (low and high) treatments between November 2003 and August 2004. Shading significantly reduced biomass of S. capillifolium (P < 0.001), whilst nitrogen (N) supply significantly increased biomass (P < 0.05) suggesting that S. capillifolium was limited by N. There was no significant interaction between shading and N on biomass. S. capillifolium responded to shading via morphophysiological and biochemical alterations to the photosynthetic tissues such as (1) break down of anthocyanins involved in photoprotection of chloroplasts, (2) translocation of N from mineralized N or old tissues and (3) allocation of translocated N to photosynthetic pigments. The results suggest that S. capillifolium can tolerate both low and high light intensities, as well as high N supply via morphophysiological responses but does not acclimate to deep shade, since biomass was reduced. Anthocyanins rather than carotenoids appear to play an essential role in photoprotection with translocation serving as the important source of N. It has been suggested that global change in temperature and N availability may lead to increased vascular plant growth that could increase shade leading to a shift from Sphagnum spp. to vascular species in peatlands. However, the species S. capillifolium appears to tolerate deep shade and high N deposition due to the mechanisms shown here suggesting that this species may continue to persist in peatland ecosystems.     

狭眼凤尾蕨配子体发育及其成精子囊素对水蕨配子体发育的影响

对狭眼凤尾蕨（Pteris biaurita）配子体发育特征及其外源成精子囊素对模式植物水蕨（Ceratopteris thalictroides）在黑暗和光照条件下孢子萌发和配子体发育的影响进行了研究。结果表明：（1）狭眼凤尾蕨孢子深褐色,三裂缝,孢子萌发为书带蕨型,原叶体发育为水蕨型,无毛状体产生;培养发现,其配子体能产生精子器,但不产生颈卵器,当接种密度适中时,可进行无配子生殖。（2）在光照和黑暗条件下狭眼凤尾蕨成精子囊素有促进和抑制水蕨孢子萌发的作用,但效果均不显著。（3）在光照条件下,狭眼凤尾蕨成精子囊素可以延迟水蕨心脏形配子体分生组织缺刻的形成,但对其配子体形态和性别分化无明显影响;而在黑暗条件下狭眼凤尾蕨成精囊素对水蕨长条形配子体的形态发育具有一定影响,与对照组相比其顶端分生组织发达,整体呈长楔形,对性别分化影响不显著。可见,狭眼凤尾蕨和水蕨不具有同种成精子囊素系统。     

Dynamics of spore germination and mycelial growth of streptomycetes under low humidity conditions

At extremely low values of moisture pressure (?96.4 MPa; a_w 0.50), the spores of xerotolerant streptomycetes (Streptomyces odorifer and S. rubiginosohelvolus) germinated, their germ lengths increased, and lateral branching of the mycelium was observed after 5 days of incubation in a thin layer of agarized nutrient medium. At ?22.6 MPa (a_w 0.86), the mycelium begins to branch after a 2-day incubation; over a 5-day incubation at ?2.8 MPa (a_w 0.98), it goes through a reproduction cycle, which culminates in spore formation. The mathematical model approach enabled us to elucidate the behavioral patterns of Streptomyces spores in a thin layer of agarized nutrient medium at low humidity levels. The dynamics of spore germination is governed by the exponential law, which allows calculation of the average duration of the period a before spore germination, as well as the time needed for 50% of viable spores to germinate.