Leaf mineral nutrition of Arctic plants in response to warming and deeper snow in northern Alaska

Articulating the consequences of global climate change on terrestrial ecosystem biogeochemistry is a critical component of Arctic system studies. Leaf mineral nutrition responses of tundra plants is an important measure of changes in organismic and ecosystem attributes because leaf nitrogen and carbon contents effect photosynthesis, primary production, carbon budgets, leaf litter, and soil organic matter decomposition as well as herbivore forage quality. In this study, we used a long term experiment where snow depth and summer temperatures were increased independently and together to articulate how a series of climate change scenarios would affect leat N, leaf C, and leaf C:N for vegetation in dry and moist tussock tundra in northern Alaska, USA. Our findings were: 1) moist tundra vegetation is much more responsive to this suite of climate change scenarios than dry tundra with up to a 25% increase in leaf N; 2) life forms exhibit divergence in leaf C, N, and C:N with deciduous shrubs and graminoids having almost identical leaf N contents; 3) for some species, leaf mineral nutrition responses to these climate change scenarios are tundra type dependent (Betula), but for others (Vaccinium vitis-idaea), strong responses are exhibited regardless of tundra type; and 4) the seasonal patterns and magnitudes of leaf C and leaf N in deciduous and evergreen shrubs were responsive to conditions of deeper snow in winter. Leaf N is was generally higher immediately after emergence from the deep snow experimental treatments and leaf N was higher during the subsequent summer and fall, and the leaf C:N were lower, especially in deciduous shrubs. These findings indicate that coupled increases in snow depth and warmer summer temperatures will alter the magnitudes and patterns of leaf mineral nutrition and that the longterm consequences of these changes may feed-forward and affect ecosystem processes.

[1]  F. Chapin,et al.  Global Warming and Terrestrial Ecosystems: A Conceptual Framework for Analysis , 2000 .

[2]  A. Michelsen,et al.  Vascular plant 15N natural abundance in heath and forest tundra ecosystems is closely correlated with presence and type of mycorrhizal fungi in roots , 1998, Oecologia.

[3]  F. Chapin,et al.  Seasonal movement of nutrients in plants of differing growth form in an Alaskan tundra ecosystem: implications for herbivory. , 1980 .

[4]  M. H. Jones,et al.  Long-term experimental manipulation of winter snow regime and summer temperature in arctic and alpine tundra , 1999 .

[5]  J. Welker,et al.  Early Spring Nitrogen Uptake by Snow-Covered Plants: A Comparison of Arctic and Alpine Plant Function under the Snowpack , 2000 .

[6]  M. H. Jones,et al.  Carbon dioxide fluxes in moist and dry arctic tundra during the snow-free season: responses to increases in summer temperature and winter snow accumulation , 1998 .

[7]  Barrie Maxwell,et al.  2 – Arctic Climate: Potential for Change under Global Warming , 1992 .

[8]  T. Callaghan,et al.  Growth responses of four sub-Arctic dwarf shrubs to simulated environmental change , 1994 .

[9]  F. Chapin,et al.  Tundra Plant Uptake of Amino Acid and NH4+ Nitrogen in Situ: Plants Complete Well for Amino Acid N , 1996 .

[10]  Thomas J. Givnish,et al.  On the economy of plant form and function. , 1988 .

[11]  F. S. Chapin,et al.  The Mineral Nutrition of Wild Plants Revisited: A Re-evaluation of Processes and Patterns , 1999 .

[12]  F. Stuart Chapin,et al.  Individualistic Growth Response of Tundra Plant Species to Environmental Manipulations in the Field , 1985 .

[13]  M. H. Jones,et al.  Annual CO2 Flux in Dry and Moist Arctic Tundra: Field Responses to Increases in Summer Temperatures and Winter Snow Depth , 2000 .

[14]  E. Rastetter,et al.  Vegetation characteristics and primary productivity along an arctic transect: implications for scaling‐up , 1999 .

[15]  R. White,et al.  Habitat Preference and Forage Consumption by Reindeer and Caribou near Atkasook, Alaska , 1980 .

[16]  J. Welker,et al.  CO2 exchange in three Canadian High Arctic ecosystems: response to long‐term experimental warming , 2004 .

[17]  J. Welker,et al.  Ecological significance of litter redistribution by wind and snow in arctic landscapes , 2000 .

[18]  F. Stuart Chapin,et al.  Responses of Arctic Tundra to Experimental and Observed Changes in Climate , 1995 .

[19]  Christopher B. Field,et al.  photosynthesis--nitrogen relationship in wild plants , 1986 .

[20]  G. Henry,et al.  Open‐top designs for manipulating field temperature in high‐latitude ecosystems , 1997 .

[21]  F. Stuart Chapin,et al.  Primary and secondary stem growth in arctic shrubs: implications for community response to environmental change , 2002 .

[22]  G. Shaver,et al.  Mineral nutrition and leaf longevity in an evergreen shrub, Ledum palustre ssp. decumbens , 1981, Oecologia.

[23]  F. Chapin,et al.  Productivity and Nutrient Cycling of Alaskan Tundra: Enhancement by Flowing Soil Water , 1988 .

[24]  G. Henry,et al.  Tundra plants and climate change: the International Tundra Experiment (ITEX) , 1997 .

[25]  F. S. Chapin,et al.  The Mineral Nutrition of Wild Plants , 1980 .

[26]  J. Schimel,et al.  Increased snow depth affects microbial activity and nitrogen mineralization in two Arctic tundra communities , 2004 .

[27]  D. Briske,et al.  Clonal biology of the temperate, caespitose, graminoid Schizachyrium scoparium : A synthesis with reference to climate change , 1992 .

[28]  S. Hobbie Temperature and plant species control over litter decomposition in Alaskan tundra , 1996 .

[29]  J. Welker,et al.  Warming chambers stimulate early season growth of an arctic sedge: results of a minirhizotron field study , 2005, Oecologia.

[30]  Robert D. Hollister,et al.  RESPONSES OF TUNDRA PLANTS TO EXPERIMENTAL WARMING:META‐ANALYSIS OF THE INTERNATIONAL TUNDRA EXPERIMENT , 1999 .

[31]  T. Callaghan,et al.  Leaf carbon isotope discrimination and vegetative responses of Dryas octopetala to temperature and water manipulations in a High Arctic polar semi-desert, Svalbard , 1993, Oecologia.

[32]  T. Valone Group foraging, public information, and patch estimation , 1989 .

[33]  W. Brand,et al.  Short-term variations in δ13C of ecosystem respiration reveals link between assimilation and respiration in a deciduous forest , 2004, Oecologia.

[34]  U. Molau,et al.  Responses of Dryas octopetala to ITEX environmental manipulations: a synthesis with circumpolar comparisons , 1997 .

[35]  Knute J. Nadelhoffer,et al.  13 – Microbial Processes and Plant Nutrient Availability in Arctic Soils , 1992 .

[36]  G. Shaver,et al.  WITHIN-STAND NUTRIENT CYCLING IN ARCTIC AND BOREAL WETLANDS , 1999 .

[37]  James F. Reynolds,et al.  Landscape Function and Disturbance in Arctic Tundra , 1996, Ecological Studies.

[38]  F. Stuart Chapin,et al.  A TRANSIENT, NUTRIENT‐BASED MODEL OF ARCTIC PLANT COMMUNITY RESPONSE TO CLIMATIC WARMING , 2000 .

[39]  C. Duarte,et al.  Patterns in decomposition rates among photosynthetic organisms: the importance of detritus C:N:P content , 1993, Oecologia.

[40]  C. Körner The nutritional status of plants from high altitudes , 1989, Oecologia.

[41]  J. Welker,et al.  Experimental manipulations of snow‐depth: effects on nutrient content of caribou forage , 1997 .

[42]  U. Molau,et al.  Effects of snowmelt timing on leaf traits, leaf production, and shoot growth of alpine plants : Comparisons along a snowmelt gradient in northern Sweden , 1999 .

[43]  S. Hobbie,et al.  Foliar and soil nutrients in tundra on glacial landscapes of contrasting ages in northern Alaska , 2002, Oecologia.

[44]  J. Welker,et al.  CO2 FLUX IN ARCTIC AND ALPINE DRY TUNDRA : COMPARATIVE FIELD RESPONSES UNDER AMBIENT AND EXPERIMENTALLY WARMED CONDITIONS , 1999 .

[45]  D. Walker,et al.  Terrain and Vegetation of the Imnavait Creek Watershed , 1996 .

[46]  F. S. Chapin,et al.  Response to fertilization by various plant growth forms in an Alaskan tundra: nutrient accumulation and growth , 1980 .

[47]  Susan E. Trumbore,et al.  Controls over carbon storage and turnover in high‐latitude soils , 2000, Global change biology.