Relationship between severity of trunk decay of Pinus koraiensis and soil properties around roots

Huadong Xu; Wenjing Chen; Yanjun Cao; Lihai Wang

doi:10.1007/s11676-020-01158-y

Journal of Forestry Research ›› 2020, Vol. 32 ›› Issue (3) : 1213 -1220. DOI: 10.1007/s11676-020-01158-y

Original Article

Relationship between severity of trunk decay of Pinus koraiensis and soil properties around roots

Author information +

History +

PDF

Abstract

The decay rate of standing Korean pine (Pinus koraiensis) in natural forests can be as high as 50% and is likely influenced by the soil properties and nutrient and water status of the site. To clarify the relationship between the severity of tree decay and soil properties in order to prevent decay in a natural mixed forest in the Xiaoxing’an Mountains, wood strength of standing trees was nondestructively assessed, and the severity of decay of extracted wood cores was quantified based on differences in mass between two decayed increment cores extracted at breast height and an intact increment core near the decayed ones. Soil samples from the critical root zone (non-rhizosphere) of each tree were analyzed for chemical properties and microbial composition. The abundance of chemical elements (especially total N and K) and the species richness of soil microbes increased as decay severity increased. Fungal number (FN) and actinomycetes number (AN) were related to decay severity (R ² = 0.504). Bacterial number (BN) was higher than FN or AN, but had a minor effect on tree decay. Path analysis showed BN might indirectly inhibit decay by affecting FN. Decay severity was not significantly correlated with either soil fungal or bacterial diversity. These results suggest that forest managers need to monitor levels of fungi and total N and total K levels to reduce the decay of Korean pine.

Keywords

Pinus koraiensis / Soil chemical properties / Soil microbial properties / Trunk decay degree

Cite this article

Download citation ▾

Huadong Xu, Wenjing Chen, Yanjun Cao, Lihai Wang. Relationship between severity of trunk decay of Pinus koraiensis and soil properties around roots. Journal of Forestry Research, 2020, 32(3): 1213-1220 DOI:10.1007/s11676-020-01158-y

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Bates ST, Clemente JC, Flores GE, Walters WA, Parfrey LW, Noah-Fiereret PK. Global biogeography of highly diverse protistan communities in soil. ISME J, 2013, 7: 652-659.

[2]	Bednarz JC, Huss MJ, Benson TJ, Varland DE. The efficacy of fungal inoculation of live trees to create wood decay and wildlife-use trees in managed forests of western Washington. USA For Ecol Manage, 2013, 307(6): 186-195.

[3]	Cai ZC, Huang XQ. Soil-borne pathogens should not be ignored by soil science. Acta Pedol Sin, 2016, 53(2): 305-310.

[4]	Chen SC. A preliminary study on the spread of the hidden rot of Abies in southwest forest area. Scientia Silvae Sinicae, 1959, 5(1): 55-67.

[5]	Goedert JJ, Jones G, Hua X, Xu X, Yu GQ, Flores R, Falk RT, Gail MH, Shi JX. Investigation of the association between the fecal microbiota and breast cancer in postmenopausal women: A population-based case-control pilot study. JNCI J Natl Cancer Inst, 2015

[6]	Hietala AM, Nagy NE, Burchardt EC, Solheim H. Interactions between soil pH, wood heavy metal content and fungal decay at Norway spruce stands. Appl Soil Ecol, 2016, 107: 237-243.

[7]	Hu YL, Wang SL, Zeng DH. Effects of single Chinese fir and mixed leaf litters on soil chemical, microbial properties and soil enzyme activities. Plant Soil, 2006, 282(1–2): 379-386.

[8]	Larsson E, Ryberg M, Moreau PA, Delcuse MA, Jacobsson S. Taxonomy and evolutionary relationships within species of section Rimosae (Inocybe) based on ITS LSU and mtSSU sequence data. Persoonia, 2009, 23(1): 86-98.

[9]	Li XY, Dong SB, Wang JN. Occurrence and control of root rot of Pinus koraiensis. China Sci Technol Inf, 2014, 12: 164-164.

[10]	Liu HT. Plylogeny and renaming of Cryptococcus podzolicus are related strains, 2016, Guizhou: Guizhou Medical University.

[11]	Liu ZX, Wang LH, Bao ZY, Sun TY. Quantitative detection of internal decay degree in Korean pine standing. J Northeast For Univ, 2015, 43(6): 89-92.

[12]	Lv J, Qu SM. Variety of economic value of development utilize of Korean pine. For Investig Des, 2010, 2: 70-71.

[13]	Martiny JBH, Bohannan BJM, Brown JH, Colwell RK, Fuhrman JA, Green JL, Horner-Devine MC, Kane M, Krumins JA, Kuske CR, Morin PJ, Naeem S, Øvreås L, Reysenbach AL, Smith VH, Staley JT. Microbial biogeography: putting microorganisms on the map. Nat Rev Microbiol, 2006, 4(2): 102-112.

[14]	Pietri JCA, Brookes PC. Relationships between soil pH and microbial properties in a UK arable soil. Soil Biol Biochem, 2008, 40(7): 1856-1861.

[15]	Shang B. The wood rotting fungi and soil fungi of the two dominate forest types in Songshan, 2008, Beijing: Beijing Forestry University 10 15

[16]	Shortle WC, Dudzik KR (2012) Wood decay in living and dead trees: a pictorial overview. General Technical Report NRS-97. United States Department of Agriculture Forest Service 2012. https://pdfs.semanticscholar.org/57c1/79af908ff583353e2bd5c6b64c8012753af5.pdf

[17]	Sun TY, Wang LH, Xu HD, Bao ZY. Effect of soil physical-chemical properties on the decay of standing Pinus koraiensis in Xiaoxing’an Mountains, northeast China. J For Res, 2015, 26(4): 859-865.

[18]	Wang YT, Xu HD, Wang LH. Rate of Korean pine standing trees in natural forests in Lesser Xing’an Mountains. J Beijing For Univ, 2015, 37(8): 97-104.

[19]	Xu HD, Di YN, Cao YJ, Wang LH, Wang HB. Relationship between cultural soil microbial quantity and Butt Decay Degree of Pinus koraiensis Standing Tree. J Northeast For Univ, 2019, 47(1): 52-55.