土壤微生物对不同种源乌桕生长的影响

【背景】土壤微生物对植物成功入侵具有重要影响,研究中国本地土壤微生物对美国入侵种乌桕的净生长效应有利于进一步理解乌桕成功入侵的机理。【方法】以本地和入侵2个种源多个种群的乌桕为试验材料,通过对土壤进行灭菌处理,研究土壤微生物对不同种源乌桕幼苗生长的影响。【结果】土壤微生物对入侵种乌桕具有正效应,与本地种相比,入侵种乌桕幼苗总生物量、相对生长速度、根冠比以及总叶面积、叶面积比、比叶面积等生物学指标在新鲜土壤中均表现出明显优势。种源和土壤处理间存在交互效应的指标显示土壤微生物去除对入侵种乌桕的抑制作用更为明显。这一结果与土壤自然天敌逃逸假说相背,入侵种乌桕在一定程度上具有较本地种更强的土壤微生物利用能力,在非根际土壤微生物的作用下入侵种乌桕具有较强的生长能力和明显的竞争优势。【结论与意义】本研究证实土壤微生物可能对乌桕成功入侵具有不可忽略的作用。由于该试验在乌桕起源地进行,结合在乌桕入侵地进行的研究有助于进一步分析土壤微生物对入侵的贡献作用;研究土壤微生物与入侵植物的互作关系有助于对入侵物种进行准确预测和有效控制,减少生物入侵对生态系统功能的破坏。     

Aboveground herbivory increases soil nematode abundance of an invasive plant

入侵植物往往可以影响土壤线虫的群落结构。然而,入侵植物在入侵地并未完全逃逸地上植食性昆虫的取食危害,而我们对昆虫取食是否会调节入侵植物对土壤线虫群落的影响还知之甚少。在本研究中,我们探讨了地上植食性昆虫取食危害如何调节入侵植物空心莲子草(Alternanthera philoxeroides)对土壤线虫群落的影响,并研究了昆虫调节作用的时间效应。我们开展温室实验,对盆栽的空心莲子草施加三种不同的昆虫取食处理[无昆虫取食、专食性昆虫莲草直胸跳甲(Agasicles hygrophila)取食、广食性昆虫虾钳菜披龟甲(Cassida piperata)取食],并在移除所有植食性昆虫后的第1、10和20天测定土壤线虫的群落结构。此外,我们还测定了空心莲子草根系及根系分泌物的碳含量。研究发现,在植食性昆虫被移除的第1天,昆虫取食处理显著提高了空心莲子草根围土壤线虫的丰度,特别是植食性线虫。然而,随着时间推移,这种影响逐渐减退,并在后期(第10和20天)完全消失。此外,专食性昆虫莲草直胸跳甲和广食性昆虫虾钳菜披龟甲的取食危害对土壤线虫丰度的影响并无显著性差异。综上所述,本研究表明地上植食性昆虫的取食危害可以改变入侵植物对土壤线虫群落的影响,但昆虫的调节作用是短暂的。此外,我们的研究强调了在评估入侵植物的影响时,需要同时考虑地上和地下生物群落。     

土壤养分对菊科一年生入侵种和本地种繁殖性状的影响

入侵植物繁殖性状的研究可为揭示植物入侵机制提供重要的科学依据。为研究土壤养分对入侵植物和本地植物繁殖性状的影响, 并进一步研究养分添加是否更能促进入侵植物的繁殖能力, 我们设置了低、高两个养分水平, 通过同质园实验比较了不同土壤养分对假臭草(Praxelis clematidea)、胜红蓟(Ageratum conyzoides)、三叶鬼针草(Bidens pilosa) 3种菊科一年生入侵种和夜香牛(Vernonia cinerea)、一点红(Emilia sonchifolia)、墨旱莲(Eclipta prostrata) 3种本地种繁殖性状的影响。研究结果显示, 养分添加提高了6种菊科植物的开花株高、株高、地上生物量、单粒种子重量、总花序数、每花序种子数、总种子数量、总种子重量, 并使开花时间提前、花期延长。养分添加对入侵种的开花株高和单粒种子重量的提高幅度要比本地种更显著。相对于部分本地植物(夜香牛、墨旱莲), 养分添加更能促进部分入侵植物(假臭草、胜红蓟)的繁殖能力。三叶鬼针草和一点红的总种子数量和总种子重量在两种土壤养分水平下均较小。本地种墨旱莲的总种子数量和总种子重量在低养分条件下高于3个入侵种。这些结果表明, 高土壤养分仅能促进部分入侵植物相对于部分本地植物的繁殖能力。     

Native and non‐native grasses generate common types of plant–soil feedbacks by altering soil nutrients and microbial communities

Soil conditioning occurs when plants alter features of their soil environment. When these alterations affect subsequent plant growth, it is a plant soil feedback. Plant–soil feedbacks are an important and understudied aspect of aboveground–belowground linkages in plant ecology that influence plant coexistence, invasion and restoration. Here, we examine plant–soil feedback dynamics of seven co‐occurring native and non‐native grass species to address the questions of how plants modify their soil environment, do those modifications inhibit or favor their own species relative to other species, and do non‐natives exhibit different plant–soil feedback dynamics than natives. We used a two‐phase design, wherein a first generation of plants was grown to induce species‐specific changes in the soil and a second generation of plants was used as a bioassay to determine the effects of those changes. We also used path‐analysis to examine the potential chain of effects of the first generation on soil nutrients and soil microbial composition and on bioassay plant performance. Our findings show species‐specific (rather than consistent within groups of natives and non‐natives) soil conditioning effects on both soil nutrients and the soil microbial community by plants. Additionally, native species produced plant–soil feedback types that benefit other species more than themselves and non‐native invasive species tended to produce plant–soil feedback types that benefit themselves more than other species. These results, coupled with previous field observations, support hypotheses that plant–soil feedbacks may be a mechanism by which some non‐native species increase their invasive potential and plant–soil feedbacks may influence the vulnerability of a site to invasion.     

Invasive plants differentially affect soil biota through litter and rhizosphere pathways: a meta‐analysis

Invasive plants affect soil biota through litter and rhizosphere inputs, but the direction and magnitude of these effects are variable. We conducted a meta‐analysis to examine the different effects of litter and rhizosphere of invasive plants on soil communities and nutrient cycling. Our results showed that invasive plants increased bacterial biomass by 16%, detritivore abundance by 119% and microbivore abundance by 89% through litter pathway. In the rhizosphere, invasive plants reduced bacterial biomass by 12%, herbivore abundance by 55% and predator abundance by 52%, but increased AM fungal biomass by 36%. Moreover, CO₂ efflux, N mineralisation rate and enzyme activities were all higher in invasive than native rhizosphere soils. These findings indicate that invasive plants may support more decomposers that in turn stimulate nutrient release via litter effect, and enhance nutrient uptake by reducing root grazing but forming more symbioses in the rhizosphere. Thus, we hypothesise that litter‐ and root‐based loops are probably linked to generate positive feedback of invaders on soil systems through stimulating nutrient cycling, consequently facilitating plant invasion. Our findings from limited cases with diverse contexts suggest that more studies are needed to differentiate litter and rhizosphere effects within single systems to better understand invasive plant‐soil interactions.     

Effects of exotic plant invasion on soil nitrogen availability

外来植物入侵对土壤氮循环和氮有效性的影响是入侵成功或进一步加剧的重要原因。通过对比相同研究地点入侵区域和无入侵区域的土壤原位氮状态差异, 探讨了外来植物入侵对土壤氮有效性的影响程度和生理生态学机制。基于107篇相关研究文献数据的整合, 发现植物入侵区域相对于无入侵区域土壤总氮、铵态氮、硝态氮、无机氮、微生物生物量氮含量显著增加, 增幅分别为(50 ± 14)%、(60 ± 24)%、(470 ± 115)%、(69 ± 25)%、(54 ± 20)%。土壤硝态氮含量增幅较大反映硝化作用增强, 这可能增加入侵植物硝态氮利用以及喜硝植物的共存。温带地区植物入侵后土壤的硝态氮含量增幅显著高于亚热带地区。固氮植物入侵后土壤的总氮和无机氮含量增幅均显著高于非固氮植物入侵。木本和常绿植物入侵后土壤的总氮含量增幅分别高于草本和落叶植物入侵; 而土壤铵态氮含量的增幅没有显著差异且与固氮入侵植物占比无明显关系; 然而硝态氮含量的增幅普遍较高且与固氮入侵植物占比显著正相关。外来入侵植物固氮功能以及凋落物质量和数量是影响土壤氮矿化和硝化过程的关键因素。该研究为理解外来植物入侵成功和加剧的机制以及入侵植物功能性状与土壤氮动态之间的关系提供了新的见解。     

外来植物入侵对土壤氮有效性的影响

外来植物入侵对土壤氮循环和氮有效性的影响是入侵成功或进一步加剧的重要原因。通过对比相同研究地点入侵区域和无入侵区域的土壤原位氮状态差异, 探讨了外来植物入侵对土壤氮有效性的影响程度和生理生态学机制。基于107篇相关研究文献数据的整合, 发现植物入侵区域相对于无入侵区域土壤总氮、铵态氮、硝态氮、无机氮、微生物生物量氮含量显著增加, 增幅分别为(50 ± 14)%、(60 ± 24)%、(470 ± 115)%、(69 ± 25)%、(54 ± 20)%。土壤硝态氮含量增幅较大反映硝化作用增强, 这可能增加入侵植物硝态氮利用以及喜硝植物的共存。温带地区植物入侵后土壤的硝态氮含量增幅显著高于亚热带地区。固氮植物入侵后土壤的总氮和无机氮含量增幅均显著高于非固氮植物入侵。木本和常绿植物入侵后土壤的总氮含量增幅分别高于草本和落叶植物入侵; 而土壤铵态氮含量的增幅没有显著差异且与固氮入侵植物占比无明显关系; 然而硝态氮含量的增幅普遍较高且与固氮入侵植物占比显著正相关。外来入侵植物固氮功能以及凋落物质量和数量是影响土壤氮矿化和硝化过程的关键因素。该研究为理解外来植物入侵成功和加剧的机制以及入侵植物功能性状与土壤氮动态之间的关系提供了新的见解。     

三叶鬼针草与不同本地植物竞争对土壤 微生物和土壤养分的影响

入侵植物三叶鬼针草(Bidens pilosa)对我国农牧业生产造成了重大的损失。本文主要研究三叶鬼针草入侵与不同本地植物竞争对土壤微生物群落结构和土壤养分的影响。利用磷脂脂肪酸方法(phospholipid fatty acids, PLFAs)测定土壤微生物群落组成, 同时测定土壤养分和酶活性, 并利用Canoco4.5软件分析了土壤微生物、土壤养分和土壤酶活性的相关性。结果表明: (1)三叶鬼针草对革兰氏阳性菌、革兰氏阴性菌、丛枝菌根真菌等土壤微生物具有较强的聚集能力, 且其根际土壤聚集的微生物类群与本地植物种类密切相关。(2)三叶鬼针草入侵显著增加了入侵地土壤的有机碳含量, 降低了铵态氮的含量; 土壤中的速效钾、速效磷和硝态氮的含量则与本地植物种类密切相关。(3)相关性分析表明, 16:00和16:1 ω5c对铵态氮的含量影响较大, 而三叶鬼针草入侵地16:00和16:1 ω5c的含量显著高于裸土对照, 进而推测这一状况导致了铵态氮含量的降低。(4) 15:1 anteiso A和18:1 ω5c与速效钾的含量呈显著正相关, 而其含量在狗尾草(Setaria viridis)中显著高于其他处理, 三叶鬼针草与狗尾草混种处理中土壤中速效钾的含量高于其他处理。以上结果说明, 三叶鬼针草通过改变土壤微生物群落结构影响了土壤酶活性和土壤养分, 且这种改变与入侵地本地植物种类有关。     

外来入侵植物对土壤氮转化主要过程及相关微生物的影响

外来入侵植物不仅影响植物群落组成、生物多样性以及生态系统的结构和功能, 而且显著影响土壤氮(N)的转化过程。外来入侵植物对N循环影响的研究已成为入侵生态学的研究热点。N循环与凋落物的分解和养分释放有关, 外来入侵植物能够改变凋落物的组成与结构, 进而影响土壤的N转化过程。另外, 外来入侵植物的化感作用也会影响土壤N转化过程, 这些作用与土壤微生物的结构与功能变化密不可分。该文主要从凋落物分解与养分释放及外来入侵植物化感作用两个方面综述了外来入侵植物对土壤N转化的影响, 总结了外来入侵植物对土壤N转化相关土壤微生物(尤其是氨氧化细菌与氨氧化古菌)的影响, 探讨了土壤N转化对外来植物入侵的反馈, 并探讨了丛植菌根真菌与外来入侵植物的互相影响。     

Effects of plant invasion on soil nitrogen transformation processes and its associated microbes

外来入侵植物不仅影响植物群落组成、生物多样性以及生态系统的结构和功能, 而且显著影响土壤氮(N)的转化过程。外来入侵植物对N循环影响的研究已成为入侵生态学的研究热点。N循环与凋落物的分解和养分释放有关, 外来入侵植物能够改变凋落物的组成与结构, 进而影响土壤的N转化过程。另外, 外来入侵植物的化感作用也会影响土壤N转化过程, 这些作用与土壤微生物的结构与功能变化密不可分。该文主要从凋落物分解与养分释放及外来入侵植物化感作用两个方面综述了外来入侵植物对土壤N转化的影响, 总结了外来入侵植物对土壤N转化相关土壤微生物(尤其是氨氧化细菌与氨氧化古菌)的影响, 探讨了土壤N转化对外来植物入侵的反馈, 并探讨了丛植菌根真菌与外来入侵植物的互相影响。     

Inoculation with native soil improves seedling survival and reduces non-native reinvasion in a grassland restoration

Losses of grasslands have been largely attributed to widespread land-use changes, such as conversion to row-crop agriculture. The remaining tallgrass prairie faces further losses due to biological invasions by non-native plant species, often with resultant ecosystem degradation. Of critical concern for conservation, restoration of native grasslands has been met with little success following eradication of non-native plants. In addition to the direct and indirect effects of non-native invasive plants on beneficial soil microbes, management practices targeting invasive species may also negatively affect subsequent restoration efforts. To assess mechanisms limiting germination and survival of native species and to improve native species establishment, we established six replicate plots of each of the following four treatments: (1) inoculated with freshly collected prairie soil with native seeds; (2) inoculated with steam-pasteurized soil with native seeds; (3) noninoculated with native seeds; or (4) noninoculated/nonseeded control. Inoculation with whole soil did not improve seed germination; however, addition of whole soil significantly improved native species survival, compared to pasteurized soil or noninoculated treatments. Inoculation with whole soil significantly decreased reestablishment of non-native invasive Bothriochloa bladhii (Caucasian bluestem); at the end of the growing season, plots receiving whole soil consisted of approximately 30% B. bladhii cover, compared to approximately 80% in plots receiving no soil inoculum. Our results suggest invasion and eradication efforts negatively affect arbuscular mycorrhizal hyphal and spore abundances and soil aggregate stability, and inoculation with locally adapted soil microbial communities can improve metrics of restoration success, including plant species richness and diversity, while decreasing reinvasion by non-native species.     

Invasion of the alien shrub Prunus laurocerasus in suburban deciduous forests: Effects on native vegetation and soil properties

Most invading alien plants affect native biodiversity and ecosystem functioning. In a field survey, we assessed the impact of the invasive shrub Prunus laurocerasus on the native vegetation and soil properties in suburban deciduous forests in the region of Basel, Switzerland. We installed four pairs of plots in patches of P. laurocerasus and in adjacent not invaded areas in each of twelve forest areas. Native species richness, Shannon-diversity and species composition of the ground vegetation and shrub layer were assessed in each plot. Furthermore, in each plot we measured physical and soil chemical characteristics, enzyme activities and the carbon source utilization pattern of the soil microbial community using Ecoplates™. The maximum age of P. laurocerasus in each plot was determined using tree ring analysis, indicating the time elapsed since the invasive plant has established. A lower native plant species richness in both the ground vegetation and shrub layer was observed in plots with presence of P. laurocerasus. A different species composition of the ground vegetation was also found among plots with and without the invasive shrub. Plots invaded by P. laurocerasus had a lower soil moisture content than control plots. The intensity, diversity and substrate richness of the carbon sources were increased in soil from invaded plots compared to soil in control plots. However, the chemical soil characteristics examined and the activities of enzymes were not influenced by the invasive plant. The effects of P. laurocerasus became more pronounced with the time elapsed since the invasive plant has established. Thus, the removal of young P. laurocerasus individuals would be an appropriate management practice for this invasive shrub species.     

Root plasticity of native and invasive Great Basin species in response to soil nitrogen heterogeneity

Soil nutrients are heterogeneously distributed in natural systems. While many species respond to this heterogeneity through root system plasticity, little is known about how the magnitude of these responses may vary between native and invasive species. We quantified root morphological and physiological plasticity of co-occurring native and invasive Great Basin species in response to soil nitrogen heterogeneity and determined if trade-offs exist between these foraging responses and species relative growth rate or root system biomass. The nine study species included three perennial bunchgrasses, three perennial forbs, and three invasive perennial forbs. The plants were grown in large pots outdoors. Once a week for 4 weeks equal amounts of ¹⁵NH₄ ¹⁵NO₃ were distributed in the soil either evenly through the soil profile, in four patches, or in two patches. All species acquired more N in patches compared to when N was applied evenly through the soil profile. None of the species increased root length density in enriched patches compared to control patches but all species increased root N uptake rate in enriched patches. There was a positive relationship between N uptake rate, relative growth rate, and root system biomass. Path analysis indicated that these positive interrelationships among traits could provide one explanation of how invasive forbs were able to capture 2 and 15-fold more N from enriched patches compared to the native grasses and forbs, respectively. Results from this pot study suggest that plant traits related to nutrient capture in heterogeneous soil environments may be positively correlated which could potentially promote size-asymmetric competition belowground and facilitate the spread of invasive species. However, field experiments with plants in different neighbor environments ultimately are needed to determine if these positive relationships among traits influence competitive ability and invader success.     

互花米草入侵对土壤生态系统的影响

互花米草是全球海岸滩涂湿地生态系统最成功的入侵植物之一,对中国沿海湿地土壤生态系统也产生了重大影响.本文主要从入侵地土壤生态系统的结构组分(土壤微生物和土壤动物)与物质循环(土壤碳循环、氮循环、磷循环和重金属元素)两大方面,综述了近年来国内外互花米草入侵对沿海滩涂与河口地区土壤生态系统的影响.此外,本文还指出了未来互花米草的研究方向,包括加强互花米草对入侵地土壤微生物的影响的研究,整合互花米草对地上、地下资源竞争和生态过程影响的研究,以及互花米草在全球变化大背景下入侵动态预测.     

Do forest soil microbes have the potential to resist plant invasion? A case study in Dinghushan Biosphere Reserve (South China)

Successful invaders must overcome biotic resistance, which is defined as the reduction in invasion success caused by the resident community. Soil microbes are an important source of community resistance to plant invasions, and understanding their role in this process requires urgent investigation. Therefore, three forest communities along successional stages and four exotic invasive plant species were selected to test the role of soil microbes of three forest communities in resisting the exotic invasive plant. Our results showed that soil microbes from a monsoon evergreen broadleaf forest (MEBF) (late-successional stage) had the greatest resistance to the invasive plants. Only the invasive species Ipomoea triloba was not sensitive to the three successional forest soils. Mycorrhizal fungi in early successional forest Pinus massonina forest (PMF) or mid-successional forest pine-broadleaf mixed forest (PBMF) soil promoted the growth of Mikania micrantha and Eupatorium catarium, but mycorrhizal fungi in MEBF soil had no significant effects on their growth. Pathogens plus other non-mycorrhizal microbes in MEBF soil inhibited the growth of M. micrantha and E. catarium significantly, and only inhibited root growth of E. catarium when compared with those with mycorrhizal fungi addition. The study suggest that soil mycorrhizal fungi of early-mid-successional forests benefit invasive species M. micrantha and E. catarium, while soil pathogens of late-successional forest may play an important role in resisting M. micrantha and E. catarium. The benefit and resistance of the soil microbes are dependent on invasive species and related to forest succession. The study gives a possible clue to control invasive plants by regulating soil microbes of forest community to resist plant invasion.     

红毛草不同程度入侵区土壤微生物群落结构和部分理化指标的比较及其相关性分析

采用磷脂脂肪酸( PLFAs)分析法比较了红毛草﹝Rhynchelytrum repens ( Willd.) C. E. Hubb.﹞非入侵区、轻度入侵区和重度入侵区土壤微生物群落结构的差异,并对不同程度入侵区土壤部分理化指标的差异进行比较;在此基础上,对土壤中不同类型微生物含量与部分理化指标的相关性进行分析。结果表明：在不同程度入侵区土壤中共检测到37种微生物,包括28种细菌、4种放线菌、4种真菌和1种原生动物,其中,细菌含量最高。6种微生物的PLFAs含量较高,且它们在3类入侵区均有分布;27种微生物的PLFAs含量较低,且它们在3类入侵区也均有分布;4种微生物的PLFAs含量较低,且它们仅分布在个别入侵区。随红毛草入侵程度加剧,土壤中细菌、真菌和原生动物的含量均逐渐升高,且它们在重度入侵区土壤中的含量分别较非入侵区增高11.34%、19.60%和13.95%;并且,土壤中的微生物种类也逐渐升高。随着红毛草入侵程度的加剧,土壤的过氧化氢酶活性逐渐下降,蔗糖酶和脲酶活性以及pH值和含水量均逐渐升高,而纤维素酶活性变化较小;与非入侵区相比,重度入侵区土壤的过氧化氢酶活性下降59.27%,而蔗糖酶和脲酶活性以及 pH 值和含水量分别升高73.71%、68.60%、15.09%和32.95%。相关性分析结果表明：土壤中的细菌含量与过氧化氢酶、蔗糖酶和脲酶活性以及pH值和含水量均存在极显著相关性(P<0.01),相关系数分别为-0.909、0.864、0.868、0.836和0.889;土壤中的真菌含量与过氧化氢酶活性存在显著负相关(P<0.05),与蔗糖酶活性和pH值存在极显著正相关,相关系数分别为-0.739、0.868和0.832。研究结果显示：红毛草能够改变土壤的微生物群落结构及理化性质,使土壤条件更利于红毛草的生长。     

Plant invasion is associated with higher plant–soil nutrient concentrations in nutrient‐poor environments

Plant invasion is an emerging driver of global change worldwide. We aimed to disentangle its impacts on plant–soil nutrient concentrations. We conducted a meta‐analysis of 215 peer‐reviewed articles and 1233 observations. Invasive plant species had globally higher N and P concentrations in photosynthetic tissues but not in foliar litter, in comparison with their native competitors. Invasive plants were also associated with higher soil C and N stocks and N, P, and K availabilities. The differences in N and P concentrations in photosynthetic tissues and in soil total C and N, soil N, P, and K availabilities between invasive and native species decreased when the environment was richer in nutrient resources. The results thus suggested higher nutrient resorption efficiencies in invasive than in native species in nutrient‐poor environments. There were differences in soil total N concentrations but not in total P concentrations, indicating that the differences associated to invasive plants were related with biological processes, not with geochemical processes. The results suggest that invasiveness is not only a driver of changes in ecosystem species composition but that it is also associated with significant changes in plant–soil elemental composition and stoichiometry.     

加拿大一枝黄花入侵对杭州湾地区土壤线虫群落的影响

近年来随着地下生态学的发展,生态学家们逐渐重视生物入侵导致的地下生物多样性及其相关生态系统功能的改变.为探究加拿大一枝黄花(Solidago canadensis)入侵对土壤线虫的影响,我们在杭州湾地区选取镇海、平湖、慈溪、奉贤、海盐和杭州6个研究地点,比较外来种加拿大一枝黄花群落与土著种芦苇(Phragmites a...     

Broussonetia papyrifera controls nutrient return to soil to facilitate its invasion in a tropical forest of Ghana

Aims Non-native invasive plants can alter soil chemistry through litter production and decomposition to facilitate their invasion. However, the important roles of these underlying processes in plant invasion remain poorly understood, particularly in tropical forest ecosystems. Here, we compared litter production, quality and decomposition of two invasive species (Broussonetia papyriferaandCedrela odorata) and two co-occurring native species (CeltismildbraediiandFuntumia elastica), and soil properties under them to elucidate their roles in the invasion of a tropical forest in Ghana.     

Differences in soil characteristics between field and forest may influence the distribution of an invasive earthworm

In northern North America, invasive earthworms (including the nightcrawler Lumbricus terrestris) have been dispersing from points of introduction and dramatically affecting soil structure, soil food webs, and forest floor dynamics. However, little is known about the factors influencing the local distribution of invasive earthworms south of the Wisconsinan glaciation. Earthworms were sampled at suspected sites of introduction near Mountain Lake Biological Field Station, Virginia, USA. The density of invasive earthworms decreased as distance from suspected sites of introduction increased; native earthworms displayed the opposite relationship. However, the distance that L. terrestris was found into the forest was less than expected given dispersal rates calculated from more northern invasions. We also found correlations among population densities of L. terrestris and physical–chemical properties of the soil, and differences between field and forest soils in terms of temperature, moisture, and soil chemical properties. We conducted two experiments to analyze some factors possibly responsible for the observed distribution: (1) temperature and moisture, and (2) soil type (field vs. forest) and food resources. Our results suggest that L. terrestris may not disperse as far into forested habitats of the Southern Appalachians compared to northern forests due to local physical‐chemical soil characteristics.