变孔异担子菌随进境针叶木传入中国的风险分析

变孔异担子菌Heterobasidion irregulare原产于北美,能引起针叶树根部和根基干部的白色腐朽病,严重时导致树木死亡。目前已扩散至欧洲部分国家,在我国尚未有分布。本研究按照植物检疫的国际标准措施之有害生物风险分析原则(ISPMNo.11),从地理分布、定殖可能性、扩散可能性、经济重要性和管理难度等方面对该病菌进行了定性分析,同时按照有害生物危险性评价指标体系及赋值标准,获得该病菌风险R值。结果显示：变孔异担子菌风险评估R值为2.35,属于高度危险林业有害生物,传入风险较高、危害大,目前尚未列入我国禁止进境检疫性有害生物名录中。因此,建议将该种真菌尽快列入名录中,加强口岸检疫。     

Production of Metal‐Chelating Compounds by Species of Heterobasidion annosum sensu lato

The role of iron and compounds that chelate iron in the development of fungal diseases and wood degradation is not well understood, and their involvement in the simultaneous pathogenic and wood‐decomposing capabilities of Heterobasidion annosum s.l. is unknown. In the current study, the production of low‐molecular‐mass compounds that can chelate iron, such as catecholate, hydroxamate and oxalate, by H. annosum s.l. was correlated positively with supplementation of the medium with iron. In contrast, iron supplementation did not increase the Fe³⁺‐reducing ability of H. annosum s.s. and H. abietinum hyphae. Indeed, H. annosum s.s. is known to cause higher mortality of the plant host, but produced a lower quantity of siderophores than H. abietinum or H. parviporum. Under iron supplementation, siderophore production was correlated with phenoloxidase activity in the low‐molecular‐mass fraction, which might have consequences for cell wall decomposition.     

Effects of sulphur dioxide and ozone on stilbenes and disease resistance in spruce trees from the Liphook Forest Fumigation Project

Levels of the stilbene glucosides astringin and isorhapontin, the main constitutive antifungal compounds in bark tissues of spruce trees, were not altered in young Picea sitchensis (Bong.) Carr. or Picea abies (L.) Karst. trees exposed to sulphur dioxide and ozone in the Liphook Forest Fumigation Project. These trees had received computer-controlled fumigation treatments with two levels of SO₂ (long-term means 13 and 22nmol mol^?1) or one level of O³ (1–3.times ambient), or a combination of these treatments, from spring until December. Resistance of bark tissues from these trees to colonization by the root- and butt-rot pathogen Heterobasidion annosum (Fr.) Bref., assessed in vitro using excised stem lengths, was not significantly altered in fumigated plants compared with those exposed to ambient pollutant levels only. This study therefore provided no evidence for altered disease resistance in P. abies and P. sitchensis trees exposed to SO² and O³.     

大伏革菌防治小孔异担子菌的菌株筛选

以从芬兰引进的野生大伏革菌、中国的大伏革菌和小孔异担子菌为研究对象,通过平板对峙培养方法,从16株大伏革菌菌株中筛选出3株防治异担子菌的高效菌株,分别为:04052、08076和08077。这3号菌株具有较高的生长速率和拮抗率,能够快速覆盖病原菌,起到显著的生防效果。实验中还发现大伏革菌生长速率和拮抗率之间存在着显著的正相关关系。     

Spruce wood degradation by Pleurotus abieticola in comparison with Phlebiopsis gigantea and Heterobasidion parviporum: in vitro experiments with isolates

The objective of this study was to evaluate the in vitro mycelium growth of Pleurotus abieticola and its competitive ability to decompose sapwood and heartwood wood, as compared to the activity of Phlebiopsis gigantea and Heterobasidion parviporum. Over the last several decades, P. gigantea has routinely been used for biocontrol of the conifer pathogen Heterobasidion annosum s.l.; however, its protective effect on Norway spruce stands was recently demonstrated to be not satisfactory. P. abieticola was proposed instead, as a promising species that might successfully compete with H. parviporum. We investigated the growth of mycelium and the ability of P. abieticola isolates to decompose wood of Norway spruce, in the experiment with isolates of P. gigantea and H. parviporum. Heartwood was better decomposed than sapwood by the majority isolates used in the experiment. Linear growth of the investigated fungi showed a more rapid mycelium development for P. gigantea and H. parviporum, compared to that of P. abieticola. In dual cultures, H. parviporum was overgrown only by P. gigantea. All the tested isolates of P. abieticola showed weaker wood decomposition than those of P. gigantea and H. parviporum. Further study is required to better understand the role of P. abieticola for the protection of spruce stands.     

Climate change induces multiple risks to boreal forests and forestry in Finland: A literature review

Climate change induces multiple abiotic and biotic risks to forests and forestry. Risks in different spatial and temporal scales must be considered to ensure preconditions for sustainable multifunctional management of forests for different ecosystem services. For this purpose, the present review article summarizes the most recent findings on major abiotic and biotic risks to boreal forests in Finland under the current and changing climate, with the focus on windstorms, heavy snow loading, drought and forest fires and major insect pests and pathogens of trees. In general, the forest growth is projected to increase mainly in northern Finland. In the south, the growing conditions may become suboptimal, particularly for Norway spruce. Although the wind climate does not change remarkably, wind damage risk will increase especially in the south, because of the shortening of the soil frost period. The risk of snow damage is anticipated to increase in the north and decrease in the south. Increasing drought in summer will boost the risk of large‐scale forest fires. Also, the warmer climate increases the risk of bark beetle outbreaks and the wood decay by Heterobasidion root rot in coniferous forests. The probability of detrimental cascading events, such as those caused by a large‐scale wind damage followed by a widespread bark beetle outbreak, will increase remarkably in the future. Therefore, the simultaneous consideration of the biotic and abiotic risks is essential.     

Impact of the biological control agent Phlebiopsis gigantea on its resident genetic structure in the Baltic Sea area

The basidiomycete Phlebiop sis gigantea (Fr.) Jülich has been used in Swedish forestry as a biocontrol agent against the root and butt-rot pathogen Heterobasidion annosum s.l. on freshly cut Picea abies stumps since the early 1990s. Until 2005, the commercial preparation of this biological stump treatment, Rotstop®, has been based on a single strain of P. gigantea that has been applied on more than 47,000 ha annually in Fennoscandia. This paper reports on the spread of genetic material from the Rotstop® biocontrol strain of P. gigantea to resident populations of P. gigantea. We conclude that the inoculated fungus remained to a large extent restricted to the treated plots and did not spread to the adjacent areas, dominated by the natural spore deposition from resident populations of the fungus. Furthermore, the study demonstrates high genetic diversity and low geographic differentiation in P. gigantea populations in the geographical area around the Baltic Sea.