The Holocene Epoch (11,700 years ago to the present) marks the development of the present-day boreal ecosystems in interior Alaska. The composition and genetics of soil microbes have the potential to alter how nutrient cycling and vegetation respond to warming and cooling events, but very little is known about how boreal soils have varied over time. Here, we use DNA sequencing on both modern soils and well-preserved paleosols developed during several episodes of the Holocene to extract information on soil bacteria, archaea, and fungi present in interior Alaska during the past 8000 years (8 ka). Community composition of bacteria and fungi in the ancient paleosols was different from modern soils, with a higher relative abundance of Proteobacteria, Chloroflexi, and Verrucomicrobia in the modern soils. The most dramatic shift in interior Alaska’s soil microbiome occurred ca. 7 ka, when species diversity was lowered and functional diversity became higher after 7 ka. This suggests that function was truly low, the early Holocene ecosystems were functionally redundant, and/or that true functional diversity was not captured due to a lack of genetic resolution in existing sequence databases. The cause of this observed shift cannot be directly answered in this work; however, these data suggest that ca. 7 ka was a critical period when microbial taxa and function shifted dramatically. This is important for understanding how the soil microbiome responds to climate changes and impacts the succession of vegetation.
AgerTAJr (1983) Holocene vegetational history of Alaska. In: WrightHE (ed.) Late Quaternary Environments of the United States: The Late Pleistocene. Minneapolis, MN: University of Minnesota Press, pp.128–141.
2.
AllisonSDMartinyJB (2008) Resistance, resilience, and redundancy in microbial communities. Proceedings of the National Academy of Sciences of the United States of America105(Suppl 1): 11512–11519.
3.
AltschulSFGishWMillerW, et al. (1990) Basic local alignment search tool. Journal of Molecular Biology215(3): 403–410.
4.
AnantharamanKBrownCTHugLA, et al. (2016) Thousands of microbial genomes shed light on interconnected biogeochemical processes in an aquifer system. Nature Communications7(1): 3219.
5.
AndersonCRCondronLMCloughTJ, et al. (2011) Biochar induced soil microbial community change: Implications for biogeochemical cycling of carbon, nitrogen and phosphorus. Pedobiologia54: 309–320.
6.
AndersonMJ (2001) A new method for nonparametric multivariate analysis of variance. Austral Ecology26: 32–46.
7.
AndersonMJ (2006) Distance-based tests for homogeneity of multivariate dispersions. Biometrics62(1): 245–253.
BaisHPWeirTLPerryLG, et al. (2006) The role of root exudates in rhizosphere interactions with plants and other organisms. Annual Review of Plant Biology57: 233–266.
11.
BaldrianPKolaříkMStursováM, et al. (2012) Active and total microbial communities in forest soil are largely different and highly stratified during decomposition. The ISME Journal6(2): 248–258.
12.
BeierSTappuRHusonDH (2017) Functional analysis in metagenomics using MEGAN 6. In: CharlesmTCLilesMRSessitschA (eds) Functional Metagenomics: Tools and Applications. Cham: Springer, pp.65–74.
13.
BigelowNHBrubakerLBEdwardsME, et al. (2003) Climate change and Arctic ecosystems: 1. Vegetation changes north of 55°N between the last glacial maximum, mid-Holocene, and present. Journal of Geophysical Research Atmospheres108: D19.
14.
BigelowNHEdwardsME (2001) A 14,000yr paleoenvironmental record from Windmill Lake, Central Alaska: Lateglacial and Holocene vegetation in the Alaska range. Quaternary Science Reviews20: 203–215.
15.
BrayJRCurtisJT (1957) An ordination of the upland forest communities of southern Wisconsin. Ecological Monographs27: 325–349.
16.
BuchfinkBXieCHusonDH (2015) Fast and sensitive protein alignment using DIAMOND. Nature Methods12: 59–60.
17.
CáceresMDLegendreP (2009) Associations between species and groups of sites: Indices and statistical inference. Ecological Monographs90: 3566–3574.
18.
CaporasoJGKuczynskiJStombaughJ, et al. (2010) QIIME allows analysis of high-throughput community sequencing data. Nature Methods7(5): 335–336.
19.
CaporasoJGLauberCLWaltersWA, et al. (2011) Global patterns of 16S rRNA diversity at a depth of millions of sequences per sample. Proceedings of the National Academy of Sciences108(suppl_1): 4516–4522.
20.
CederlundHWessénEEnwallK, et al. (2014) Soil carbon quality and nitrogen fertilization structure bacterial communities with predictable responses of major bacterial phyla. Applied Soil Ecology84: 62–68.
21.
ChapmanWLWalshJE (2007) Simulations of Arctic temperature and pressure by global coupled models. Journal of Climate20: 609–632.
22.
CostelloEKSchmidtSK (2006) Microbial diversity in alpine tundra wet meadow soil: Novel chloroflexi from a cold, water-saturated environment. Environmental Microbiology8: 1471–1486.
23.
CoxFNewshamKKBolR, et al. (2016) Not poles apart: Antarctic soil fungal communities show similarities to those of the distant Arctic. Ecology Letters19: 528–536.
24.
DandareSUYoungJMKelleherBP, et al. (2019) The distribution of novel bacterial laccases in alpine paleosols is directly related to soil stratigraphy. The Science of the Total Environment671: 19–27.
25.
DeBruynJMFawazMNPeacockAD, et al. (2013) Gemmatirosa kalamazoonesis gen. nov., sp. nov., a member of the rarely-cultivated bacterial phylum Gemmatimonadetes. The Journal of General and Applied Microbiology59: 305–312.
26.
DeBruynJMNixonLTFawazMN, et al. (2011) Global biogeography and quantitative seasonal dynamics of Gemmatimonadetes in soil. Applied and Environmental Microbiology77: 6295–6300.
27.
DouglasTAJonesMCHiemstraCA, et al. (2014) Sources and sinks of carbon in boreal ecosystems of Interior Alaska: Current and future perspectives for land managers. Elementa Science of the Anthropocene2: 000032.
28.
DufreneMLegendreP (1997) Species assemblages and indicator species: The need for a flexible asymmetrical approach. Ecological Monographs67: 345–366.
29.
EdgarRC (2010) Search and clustering orders of magnitude faster than BLAST. Bioinformatics26(19): 2460–2461.
30.
EdwardsMEMockCJFinneyBP, et al. (2001) Potential analogues for paleoclimatic variations in eastern interior Alaska during the past 14,000yr: Atmospheric-circulation controls of regional temperature and moisture responses. Quaternary Science Reviews20: 189–202.
31.
FredrikssonABallesterosMDukanS, et al. (2005) Defense against protein carbonylation by DNaK/DnaJ and proteases of the heat shock regulon. Journal of Bacteriology187: 4207–4213.
32.
FrindteKLehndorffEVlaminckS, et al. (2020) Evidence for signatures of ancient microbial life in paleosols. Scientific Reports10(1): 16830.
33.
FritzMWetterichSSchirrmeisterL, et al. (2012) Eastern Beringia and beyond: late Wisconsinan and Holocene landscape dynamics along the Yukon Coastal Plain, Canada. Palaeogeography Palaeoclimatology Palaeoecology319–320: 28–45.
34.
GagliotiBVMannDHGrovesP, et al. (2018) Aeolian stratigraphy describes ice-age paleoenvironments in unglaciated Arctic Alaska. Quaternary Science Reviews182: 175–190.
35.
GasparHFerreiraRGonzalezJM, et al. (2016) Influence of temperature and copper on Oxalobacteraceae in soil enrichments. Current Microbiology72: 370–376.
36.
GlassmanSIWangIJBrunsTD (2017) Environmental filtering by pH and soil nutrients drives community assembly in fungi at fine spatial scales. Molecular Ecology26(24): 6960–6973.
37.
GraystonSJVaughanDJonesD (1997) Rhizosphere carbon flow in trees, in comparison with annual plants: The importance of root exudation and its impact on microbial activity and nutrient availability. Applied Soil Ecology5: 29–56.
HöfleCEdwardsMEHopkinsDM, et al. (2000) The full-glacial environment of the northern Seward Peninsula, Alaska, reconstructed from the 21,500-year-old Kitluk paleosol. Quaternary Research53: 143–153.
40.
HopkinsDM (1982) Aspects of the paleogeography of Beringia during the late Pleistocene. Paleoecology of Beringia. In: HopkinsDMMatthewsJVSchwegerCE and et al. (eds) Paleoecology of Beringia. London, UK: Academic Press, pp. 3–28.
41.
HowardPJAHowardDM (1979) Respiration of decomposing litter in relation to temperature and moisture: Microbial decomposition of tree and shrub leaf litter 2. Oikos33: 457–465.
42.
HuFSBrubakerLBGavinDG, et al. (2006) How climate and vegetation influence the fire regime of the Alaskan boreal biome: The holocene perspective. Mitigation and Adaptation Strategies for Global Change11: 829–846.
43.
KellyRChipmanMLHigueraPE, et al. (2013) Recent burning of boreal forests exceeds fire regime limits of the past 10,000 years. Proceedings of the National Academy of Sciences of the United States of America110: 13055–13060.
44.
KerstersKDe VosPGillisM, et al. (2006) Introduction to the Proteo-bacteria. In: DwarkinMFalkowSRosenbergE, et al. (eds) The Prokaryotes, vol. 5, 3rd edn.New York, NY: Springer, pp.3–37.
45.
KõljalgUNilssonRHAbarenkovK, et al. (2013) Towards a unified paradigm for sequence-based identification of fungi. Molecular Ecology22: 5271–5277.
46.
LayCYBellTHHamelC, et al. (2018) Canola root-associated microbiomes in the Canadian Prairies. Frontiers in Microbiology9: 1188.
47.
LetunicIBorkP (2021) Interactive Tree of Life (iTOL) v5: An online tool for phylogenetic tree display and annotation. Nucleic Acids Research49: W293–W296.
48.
LiXRuiJXiongJ, et al. (2014) Functional potential of soil microbial communities in the maize rhizosphere. PLoS One9: e112609.
49.
LozuponeCLladserMEKnightsD, et al. (2011) UniFrac: An effective distance metric for microbial community comparison. The ISME Journal5: 169–172.
50.
McDonaldDPriceMNGoodrichJ, et al. (2012) An improved greengenes taxonomy with explicit ranks for ecological and evolutionary analyses of bacteria and archaea. The ISME Journal6: 610–618.
51.
MekonnenZARileyWJGrantRF (2018) Accelerated nutrient cycling and increased light competition will lead to 21st century shrub expansion in North American Arctic tundra. Journal of Geophysical Research Biogeosciences123(5): 1683–1701.
52.
MelvinAMMackMCJohnstoneJF, et al. (2015) Differences in ecosystem carbon distribution and nutrient cycling linked to forest tree species composition in a mid-successional boreal forest. Ecosystems18(8): 1472–1488.
53.
Mikita-BarbatoRAKellyJJTateRL (2015) Wildfire effects on the properties and microbial community structure of organic horizon soils in the New Jersey Pinelands. Soil Biology and Biochemistry86: 67–76.
54.
MorgensternIKlopmanSHibbettDS (2008) Molecular evolution and diversity of lignin degrading heme peroxidases in the Agaricomycetes. Journal of Molecular Evolution66(3): 243–257.
55.
MuhsDRAgerTABettisEAIII, et al. (2003) Stratigraphy and palaeoclimatic significance of Late Quaternary loess–palaeosol sequences of the last interglacial–glacial cycle in central Alaska. Quaternary Science Reviews22: 1947–1986.
56.
MuhsDRBudahnJR (2006) Geochemical evidence for the origin of late Quaternary loess in central Alaska. Canadian Journal of Earth Sciences43(3): 323–337.
NunanNLeloupJRuampsLS, et al. (2017) Effects of habitat constraints on soil microbial community function. Scientific Reports7(1): 4280.
59.
OksanenJKindtRLegendreP, et al. (2013) The vegan package: Community ecology package. 2007. R package version: 2-0.
60.
OverbeekROlsonRPuschGD, et al. (2014) The SEED and the rapid annotation of microbial genomes using subsystems technology (RAST). Nucleic Acids Research42: D206–D214.
61.
PetschSTEglingtonTIEdwardsKJ (2001) 14C-dead living biomass: Evidence for microbial assimilation of ancient organic carbon during shale weathering. Science292: 1127–1131.
62.
PointingSBChanYLacapDC, et al. (2009) Highly specialized microbial diversity in hyper-arid polar desert. Proceedings of the National Academy of Sciences of the United States of America106: 19964–19969.
63.
PotterBAEsdaleJAReutherJD (2018) Archaeological Investigations at Delta River Overlook, Central Alaska. Archaeology GIS Laboratory, Report #7. Fairbanks, AK: Department of Anthropology, University of Alaska Fairbanks.
64.
PriceMNDehalPSArkinAP (2010) FastTree 2-Approximately maximum-likelihood trees for large alignments. PLoS One5(3): e9490.
65.
R Core Team (2014) R: A Language and Environment for Statistical Computing Version 3.6.1. Vienna, Austria: R Foundation for Statistical Computing, Available at: http://www.R-project.org/. (accessed July 2019).
66.
Riveros-IreguiDAEmanuelREMuthDJ, et al. (2007) Diurnal hysteresis between soil CO2 and soil temperature is controlled by soil water content. Geophysical Research Letters34: L17404.
67.
RouskJBrookesPCBååthE (2009) Contrasting soil pH effects on fungal and bacterial growth suggest functional redundancy in carbon mineralization. Applied and Environmental Microbiology75: 1589–1596.
68.
Saidi-MehrabadANeubergerPHajihosseiniM, et al. (2020) Permafrost microbial community structure changes across the pleistocene-Holocene boundary. Frontiers in Environmental Science8: 133.
69.
SchulteEEHoskinsB (2009) Recommended soil organic matter tests. Chapter 8 in Recommended Soil Testing Procedures for the Northeastern United States, 3rd ed.Northeastern Regional Bulletin, No. 493.
70.
SetäläHBergMPJonesTH (2005) Chapter thirteen: Trophic structure and functional redundancy in soil communities. In: BardgettRDUsherMBHopkinsDW. (eds) Biological Diversity and Function in Soils. Cambridge: Cambridge University Press, British Ecological Society, pp.237–242.
71.
SimsJTEckertD (2009) Recommended soil pH and lime requirement tests. Chapter 3 in Recommended Soil Testing Procedures for the Northeastern United States, 3rd ed.Northeastern Regional Bulletin. No. 493.
72.
SmithDPPeayKG (2014) Sequence depth, not PCR replication, improves ecological inference from next generation DNA sequencing. PLoS One9: e90234.
73.
SterkenburgEBahrABrandström DurlingM, et al. (2015) Changes in fungal communities along a boreal forest soil fertility gradient. New Phytologist207: 1145–1158.
74.
TedersooLBahramMPõlmeS, et al. (2014) Global diversity and geography of soil fungi. Science346: 1256688.
75.
TóthEMBorsodiAK (2014) The Family Nocardiaceae. In: RodenbergEDeLongEFLoryS, et al. (eds) The Prokaryotes Volume 4: Actinobacteria. Berlin, Heidelberg: Springer Verlag, pp.651–694.
76.
TournaMStieglmeierMSpangA, et al. (2011) Nitrososphaera viennensis, an ammonia oxidizing archaeon from soil. Proceedings of the National Academy of Sciences of the United States of America108: 8420–8425.
77.
VenturaMCanchayaCTauchA, et al. (2007) Genomics of Actinobacteria: Tracing the evolutionary history of an ancient phylum. Microbiology and Molecular Biology Reviews71: 495–548.
78.
VisserS (1995) Ectomycorrhizal fungal succession in jack pine stands following wildfire. New Phytologist129: 389–401.
79.
WallensteinMDMcMahonSSchimelJ (2007) Bacterial and fungal community structure in Arctic tundra tussock and shrub soils. FEMS Microbiology Ecology59: 428–435.
80.
WearEKWilbanksEGNelsonCE, et al. (2018) Primer selection impacts specific population abundances but not community dynamics in a monthly time-series 16S rRNA gene amplicon analysis of coastal marine bacterioplankton. Environmental Microbiology20(8): 2709–2726.
81.
WolfABeegleD (2009) Recommended soil tests for macro and micronutrients. Chapter 5 in Recommended Soil Testing Procedures for the Northeastern United States, 3rd ed.Northeastern Regional Bulletin, No. 493.
82.
YeagerCMGallegos-GravesVDunbarJ, et al. (2017) Polysaccharide degradation capability of Actinomycetales soil isolates from a semiarid grassland of the Colorado Plateau. Applied and Environmental Microbiology83: e03020-16.
83.
YinBCrowleyDSparovekG, et al. (2000) Bacterial functional redundancy along a soil reclamation gradient. Applied and Environmental Microbiology66: 4361–4365.
84.
YoungJMSkvortsovTKelleherBP, et al. (2019) Effect of soil horizon stratigraphy on the microbial ecology of alpine paleosols. The Science of the Total Environment657: 1183–1193.
85.
ZakDRHolmesWEWhiteDC, et al. (2003) Plant diversity, soil microbial communities, and ecosystem function: Are there any links?Ecology84: 2042–2050.
86.
ZarillaKAPerryJJ (1984) Thermoleophilum album gen. nov. and sp. nov., a bacterium obligate for thermophily and n-alkane substrates. Archives of Microbiology137: 286–290.
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