Responses of ecosystems to climate change are complex because of multiple confounding factors acting together over a range of temporal and spatial scales (Sistla et al., 2013; Keenan et al., 2014). Natural climate gradients found along mountain slopes provide an effective way to study combined biotic and abiotic effects on ecological patterns and processes (Raich et al., 1997; King et al., 2013). As climatic conditions change with elevation, they act as a driving force for vegetation, for example, by shaping forest distribution (Peñuelas and Boada, 2003), turnover rates (Stephenson and van Mantgem, 2005), and forest structure (Holeksa et al., 2007), with resulting changes in dominant species that lead to the identification of bioclimatic zones (Di Filippo et al., 2007; Crausbay and Hotchkiss, 2010). Overall, identifying ecological gradients is one of the most powerful analytical strategies for field-based investigations on environmental controls of vegetation patterns (Whittaker, 1967).
A gradient-based approach has been used to study ecohydro-climatic drivers of tree growth in a variety of North American settings. The focus of published research has ranged from the relatively flat forested lands in Florida (Foster and Brooks, 2001) and the large expanse of the boreal biome in Quebec (Rossi et al., 2014a) to the topographically complex forest landscapes of California (Bekker and Taylor, 2001), Arizona (Fritts et al., 1965), New Mexico (Padien and Lajtha, 1992), and Nevada (LaMarche, 1974). Recently there has been an added emphasis on employing altitudinal-latitudinal gradients to study climate-growth relationships at finer spatial and temporal scales. Processes have therefore been analyzed at the individual tree level (Galván et al., 2012; van der Maaten-Theunissen and Bouriaud, 2012), using microscopic features (St-Germain and Krause, 2008; Rossi et al., 2014b), and at intra-annual time scales (de Luis et al., 2011; DeSoto et al., 2011). This increased resolution is associated with a demand for site-specific data, and newly installed networks of instrumental stations have been used to evaluate the effects of local climate on xylem formation (Deslauriers et al., 2008), tree-ring properties (Krause et al., 2010), timber quality (Rossi et al., 2014b), and ecophysiological responses of tree species from different provenances (Reinhardt et al., 2011).
In the Great Basin of North America, where climate is overall quite dry (Grayson, 2011), elevation is inversely correlated with temperature and directly correlated with precipitation (Houghton et al., 1975). A new mountain observatory composed of valley-to-mountain transects has been built in this region between 2010 and 2013 with state-of-the-art instrumentation to capture ecosystem dynamics in real time (Mensing et al., 2013). The Nevada Climate-ecohydrological Assessment Network (NevCAN) consists of stations equipped with a set of automated sensors that record climatic and environmental variables at sub-hourly time intervals. To represent biogeographic and macrosystem changes, two mountain ranges separated by about 2.5° latitude were selected. The southern site is an example of warmer and drier regions influenced by the North American Monsoon System; the northern location typifies areas dominated by cool-season precipitation and snowpack dynamics. At either location, elevation gradients span about 2000 m, thus enabling researchers to perform field studies on ecosystem processes with unprecedented detail (Johnson et al., 2014). Because of the availability of high-resolution climatic data (hourly to subhourly), detailed measurements of tree growth can be linked to intra-annual climatic events recorded by xylem rings and wood anatomy features.
Tree rings represent a unique archive of ecological and environmental information (Fritts, 2001). Dendrochronological proxy records have provided spatial and temporal indices of interannual climate variability over several centuries in all inhabited continents (Speer, 2010). Empirical relationships between tree rings and climate have also been investigated at the intra-annual level, e.g., for reconstructing summertime precipitation by means of latewood-width chronologies (Stahle et al., 2009; Griffin et al., 2013). A process-based understanding of the physiological mechanisms controlling the climatic response of woody species can be obtained using anatomical studies (Deslauriers et al., 2003; Fonti et al., 2010). In those investigations, the tree growing season is commonly sampled by means of microcores extracted at time intervals ranging from a few days to a couple of weeks. Developmental stages of xylem cells, and timing of their occurrence, can be recognized, thus revealing linear and nonlinear dynamics of xylem phenology (Rossi et al., 2013). Such intra-annual data make it possible to detect the consequences of short-term environmental signals on tree-ring formation and radial growth. In fact, microscopic wood traits (e.g., lumen area, cell diameter, wall thickness) respond to climatic and environmental conditions as much or even more, in some instances, than ring width (de Luis et al., 2011; Olano et al., 2012; Liang et al., 2013).
In conifers most of the wood is composed of tracheids, which simultaneously provide vascular transport and mechanical support (Vaganov et al., 2006). Tracheid size has been found to be positively correlated with moisture availability at the time of cell formation (Vieira et al., 2009). The cross-sectional area (lumen) of tracheids, while providing water transport and being directly linked to the hydration of the plant, depends on complex mechanical and physiological trade-offs between structural development and resistance to drought (Sperry et al., 2006). Trees hold a high degree of plasticity, and are able to adjust newly formed annual tracheids to external conditions, so that variability recorded in tree rings can be used for retrospective studies of past hydraulic adjustments to water availability (Bryukhanova and Fonti, 2013). Because cellular parameters respond to environmental conditions at the time of their formation, they also present lower time-series autocorrelation than tree-ring width (Deslauriers and Morin, 2005).
Our overall objective is to determine the climatic factors that control radial growth in Great Basin conifers. The NevCAN transects enabled us to compare wood anatomy and tree-ring characteristics among species at different elevations and at locations (north and south) with distinct climatic regimes. By testing for the existence of common variability associated with different levels of water stress, we addressed the following questions: (a) Is there a connection between growing season climate and anatomical characteristics (e.g., lumen area and cell diameter) that are related to stem water transport?, (b) How are precipitation and air temperature variables linked with intra- or interspecific variations of tree-ring and anatomical parameters?, and (c) Are environmental signals in earlywood and latewood widths the same as for cellular features?
MATERIALS AND METHODS
Study area—The NevCAN northern transect (Fig. 1) is located in the Snake Range (east-central Nevada, close to the Utah border), while the southern transect is in the Sheep Range (southern Nevada, about 50 km north of Las Vegas). The northern transect consists of eight stations starting from 1755 m a.s.l. on the western side of the range, culminating at 3355 m a.s.l. near treeline, and ending at 1560 m a.s.l. on the eastern side of the range (Fig. 1; Table 1). Both private and public landowners are involved, including the Long Now Foundation (three sites), the Bureau of Land Management (three sites), Great Basin National Park (one site), and the Nevada Land Conservancy (one site). The southern transect consists of five stations, starting at 900 m a.s.l. and ending at 3015 m a.s.l. on land managed by the U.S. Fish and Wildlife Service, and often co-located with Natural Resources Conservation Service (NRCS) Soil Climate Analysis Network (SCAN) sites.
On the west side of the Snake Range, forest cover at the montane level is composed by Pinus flexilis E. James, Pseudotsuga menziesii (Mirb.) Franco, and Abies concolor Lindl, ex Hildebr.1 Shrub layers are formed by mountain mahogany (Cercocarpus ledifolius Nutt.) and greenleaf manzanita (Arctostaphylos patula Greene). Near and at treeline, the dominant species is Pinus longaeva D. K. Bailey, mixed with scattered individuals of Picea engelmannii Parry ex Engelm. and Pinus flexilis. On the east side of the range, Picea engelmanii is the most abundant species, together with several large individuals of Populus tremuloides Michx. and some Pinus flexilis. At the Sheep Range, the lower elevations are occupied by woodlands composed of Pinus monophylla Torr. & Frém. and Juniperus osteosperma (Torr.) Little, while the montane site includes several large individuals of Pinus ponderosa var. scopulorum Engelm. together with Pinus monophylla.
Field collections—This study was conducted at five NevCAN sites (Table 1). Three sites were sampled at the Snake Range, namely the Subalpine West (Sna1-2, 3355 m a.s.l.; see below), the Subalpine East (Sna3, 3070 m a.s.l.), and the Montane West (Sna4, 2810 m a.s.l.). The Subalpine West site was subdivided in two parts, High (Sna1) and Low (Sna2), to represent two distinct groups of trees separated by about 10 m in elevation. Two sites were sampled at the Sheep Range, the Montane (She1, 2320 m a.s.l.) and the Pinyon-Juniper (She2, 2065 m a.s.l.). Four conifer species were analyzed, including Engelmann spruce (Picea engelmannii [abbreviation: PIEN]), bristlecone pine (Pinus longaeva [PILO]), limber pine (Pinus flexilis [PIFL]), and pinyon pine (Pinus monophylla [PIMO]). Each species occurred at two sites (Table 1). In the Snake Range (northern area), PILO was present at Sna1 and Sna2, PIEN at Sna1 and Sna3, and PIFL at Sna2 and Sna4. In the Sheep Range (southern area), PIMO occupied She1 and She2. Sampled stems were located in close proximity (10–15 m) of the meteorological station that recorded climate parameters (air temperature at 2 m height; total liquid and solid precipitation) at each site.
A total of 57 trees were sampled between June and September 2013. Within each population, sampled trees had similar sizes (Table 1; diameter at breast height, or dbh, was measured ca. 1.3 m above ground level) to minimize the effects of tree size on anatomical parameters (Anfodillo et al., 2012). The largest individuals were PIEN located at the western and eastern subalpine sites of the Snake Range (mean dbh was 43 and 47 cm, respectively). Wood microcores 1–2 mm wide and ca. 1 cm long were collected using a surgical bone-marrow needle or a Trephor (Rossi et al., 2006). Trees were sampled at breast height (about 1.3 m above ground level) whenever possible. In about 25% of cases, sampling took place at lower heights to avoid branch intersections and/or portions of the stem with scars or a strong leaning—hence possible reaction wood. After extraction, microcores were stored in a 50% ethanol solution to avoid tissue deterioration.
Table 1.
Summary information on study sites and sampled species.
Sample preparation and measurement—In the laboratory, microcores were dehydrated with ethanol and PROTOCOL Safeclear II (Fisher Scientific, Waltham, Massachussetts, USA) and embedded in blocks of paraffin. Several transversal sections 8–10 µm thick were cut from each sample using a Leica rotary microtome (Leica Biosystems, Buffalo Grove, Illinois, USA), then permanently mounted on glass slides. Sections were stained with safranin (0.50% in water) and images were taken at 100–200× magnification with a digital camera mounted on a microscope. Images were analyzed with WinCELL software (Guay, 2013).
Each microcore included several xylem layers, from 3–4 in fast-growing trees (PIEN at Sna3) up to 40–50 in slow-growing ones (PILO at Sna1–2). The average number of tree rings in all microcores for all species was 13, so the period 2000–2012 was selected for comparison purposes, with the only exception being PIEN at Sna1, where year 2000 was not available. Tree rings were visually cross-dated (Douglass, 1941) to assign each radial growth increment to the year of formation. Anatomical and tree-ring parameters were measured along three lines within each annual ring (Deslauriers et al., 2003). Anatomical parameters consisted of lumen area (la), cell diameter (cd), and average cell wall thickness (wt; Appendix S1 ()); ring parameters were earlywood width (EW), latewood width (LW), and total ring width (RW). EW and LW were measured by averaging the sum of tracheid diameters classified as earlywood or latewood along the three lines.
The latewood definition based on anatomical parameters that was provided by Mork has been interpreted in two different ways by different authors (Denne, 1988). In addition, other criteria to separate earlywood and latewood have been proposed when using densitometry traces (Franceschini et al., 2013). Given the anatomical emphasis of this study, we followed the criterion used by the WinCELL software (Guay, 2013), which is equivalent to “formula 2” in Denne (1988). Earlywood and latewood were also separated according to the visual identification of the first onset of lumen contraction within a ring (Stahle et al., 2009). Results based on this method showed a very high linear correlation (R2 = 0.98) with the anatomical definition, which was then used for further analyses, as it is less prone to subjective interpretations.
Data analysis—Intraspecific features were analyzed pairwise, comparing trees of the same species growing at different elevations and, for PIEN, slope exposure (west vs. east). Yearly profiles of lumen area, cell diameter, and wall thickness were standardized and averaged to create tracheidograms of anatomical parameters for the period 2000–2012. A tracheidogram displays the intra-annual variation of an anatomical parameter in the radial direction, according to its relative position (rank) within the ring (Vaganov, 1990). Standardized tracheidograms were computed using the tgram package for the R software environment (R Development Core Team, 2012), using a normalized number of 30 cells per ring (Vaganov et al., 2006). Tukey's biweight mean (Mosteller and Tukey, 1977) from the dplR package (Bunn et al., 2014) was applied to reduce the effect of outliers. Year-to-year changes in anatomical parameters were analyzed by species.
Anatomical parameters were computed separately for earlywood and latewood (e.g., lumen area of earlywood tracheids = laEW, lumen area of latewood tracheids = laLW; see Table 2). We quantified the effects of stem size on anatomical parameters by testing earlywood and latewood anatomical features against dbh. Mean chronologies of earlywood and latewood widths and their related microscopic features (lumen area, cell diameter, and wall thickness) for the period 2000–2012 were computed by species and site. Analysis of variance (ANOVA) was performed on earlywood and latewood anatomical parameters to test for differences related to elevation. Levene's test (Brown and Forsythe, 1974) was used to check the homogeneity of variance of anatomical features. The relationship between tree-ring (EW and LW) and anatomical parameters was tested for each species and site by linear correlation analysis and by graphical comparisons between normalized chronologies. Anatomical parameters of earlywood (laEW, cdEW, and wtEW) and latewood (laLW, cdLW, and wtLW) were compared to climatic variables: mean air temperature and total precipitation for spring (April–June) and summer (July–September), respectively.
Table 2.
Abbreviations of tree-ring and anatomical parameters measured in this study.
RESULTS
Climatic regime—Climatic data recorded by the NevCAN stations during the period 2010–2013 showed higher mean annual temperature at the Sheep Range (9.8°C and 11.6°C at She1 and She2) compared to the Snake Range (1.1°C, 2.3°C, and 4.7°C at Sna1–2, Sna3, and Sna4, respectively). The summer months (June–August) were the warmest ones, but water stress varied among sites. The southern area was drier, and its precipitation regime was influenced by the North American Monsoon System (Adams and Comrie, 1997). Summer precipitation (July–September) accounted for more than 50% of total annual precipitation at She1 and She2, whereas at the Snake Range fall–spring precipitation (October–May) supplied about 80% of total annual solid and liquid precipitation, in particular on the western slope (Fig. 1). On the eastern side of the Snake Range (Sna3), total annual precipitation was lower compared with the western side, but summer precipitation was more abundant (36% of total annual precipitation). At all sites June was the driest month, with almost no precipitation (Fig. 1).
Tracheidograms—Standardized tracheidograms of anatomical features (lumen area, cell diameter, wall thickness) in the period 2000–2012 showed differences related to latitude, elevation, and slope exposure ( Appendix S2 ()). PIMO, which was sampled at the southern site, had smaller lumen areas, tracheid diameter, and wall thickness than the northern species, with the exception of lumen area in PILO, which was similar (Fig. 2). At the intraspecific level, both PIMO and PIFL trees growing at the higher elevations showed larger cellular elements. Tracheid size of PIMO was constantly greater during 2000–2012 at She1 compared to She2 (median la was 433 µm2 and 333 µm2, respectively; mean cd was 23.2 µm and 19.5 µm, respectively). At the higher site, PIFL had larger tracheids in nine out of 13 years (median la was 601 µm2 at Sna2 and 585 µm2 at Sna4) and cell diameter was larger in five out of 13 years (median cd was 29.4 µm and 29.6 µm at Sna2 and Sna4, respectively).
Tracheids of the other two conifer species, PILO and PIEN, were instead larger at lower sites, a pattern more evident for Picea engelmannii than Pinus longaeva (Fig. 2). PILO had larger cell lumens and diameters at the lower part of the western subalpine site (median la was 374 µm2 at Sna1 and 474 µm2 at Sna2; median cd was 25.8 µm and 27.6 µm at Sna1 and Sna2, respectively). Cellular elements of PIEN had dimensions 20–50% greater on the east side (Sna3) than on the west side (Sna1) of the Snake Range (at Sna1 and Sna3, median la was 505 µm2 and 769 µm2, and median cd was 27.8 µm and 33.0 µm, respectively).
Thicker cell walls were usually found at the northern site and at higher elevations (Fig. 2). From 2000 to 2012, wall thickness of PIMO was constantly wider at the higher elevation (median wt was 2.7 µm at She1 and 2.5 µm at She2). Cell walls of PIEN tracheids were wider on the west side of the Snake Range, which was also at the higher elevation. Variability of anatomical parameters increased from the Sheep Range (south) to the Snake Range (north), while at the intraspecific level it increased with elevation. The highest annual variability was encountered in cell lumen area and radial diameter ( Appendix S2 ()).
Earlywood and latewood tree-ring parameters—A significant relationship emerged between anatomical parameters of earlywood and diameter of sampled trees when considering all data, without distinctions between species (Fig. 3). Earlywood lumen area (laEW) and cell diameter (cdEW) showed the highest positive correlation with stem diameter. Earlywood wall thickness (wtEW) and all the latewood parameters showed weaker or no correlation with stem diameter (Fig. 3). Variability of tree size within a species was relatively low, making comparisons possible between populations of the same tree species growing at different elevations.
ANOVA uncovered significant differences between cell dimensions of PIEN, PILO, and PIMO (Table 3). Lumen area and cell diameter of earlywood tracheids (laEW) varied between sites for these conifer species. Wall thickness of earlywood tracheids was different for PIEN and PIMO, but not for PILO. Cellular features of latewood differed between sites only in a few cases (Table 3). Latewood lumen of PILO was smaller at Sna1 compared to Sna2. At the Sheep Range the diameter of PIMO latewood tracheids (cdLW) was narrower at the lower elevation, as was the wall thickness of both earlywood (wtEW) and latewood (wtLW) tracheids. No difference with P values ≤0.005 was found between anatomical parameters of PIFL at the Sna2 and Sna4 sites (Table 3). However, differences in PIFL cell dimensions at the higher and lower sites have increased in the most recent years (Ziaco et al., 2014).
The correlation matrix of tree-ring and anatomical parameters highlighted relationships between EW, LW, and wood anatomy (Fig. 4). For each species and site, the amount of earlywood was the best predictor of total ring width (Pearson linear coefficients always >0.90). In most species, earlywood width was directly correlated with cell diameter, and in PIFL and PIMO it was also related to lumen area (Fig. 4). Latewood width was often positively correlated with both lumen area and wall thickness. For both earlywood and latewood width, no clear latitudinal or altitudinal influences were detected.
Variation of tree-ring parameters (EW and LW) mostly agreed with those of cell dimensional features related to plant water transport (la and cd) during the years 2000–2012 (Fig. 5). Year-to-year oscillations in earlywood and latewood features were usually coherent by species, with the exception of PIEN at Sna1, where EW, LW, and their related anatomical features were negatively correlated (Fig. 5).
Wood anatomical parameters showed a decreasing trend with increasing air temperature using pooled data from all species along both NevCAN transects (Fig. 6, Appendices S3 () and S4 ()). The highest correlations were found between spring temperature and earlywood parameters (cdEW, laEW, and wtEW). A positive correlation was found between these earlywood parameters and spring precipitation. Correlations were usually stronger for cdEW (Fig. 6) compared to laEW ( Appendix S3 ()) and wtEW ( Appendix S4 ()). Latewood parameters showed similar but weaker correlations with summer temperature and precipitation, most likely because of reduced variability in cellular elements (la, cd, wt) in latewood compared to earlywood. Wall thickness in both earlywood and latewood showed weak but significant correlations with climatic variables (spring/summer temperature and precipitation; Appendix S4 ()).
DISCUSSION
Altitudinal and latitudinal differences in climate regimes at the NevCAN sites were reflected in intra-annual wood anatomical traits, as seen in the mean tracheidograms, which portray average tree performance in response to environmental conditions. The effect of elevation was also found in tree dimension, as stem diameter generally increased from low to high elevations, especially when comparing trees of the same species. In this sense, temperature and precipitation represent ecological constraints that control plant size in the same way as they influence anatomical parameters, e.g., by determining maximum potential dimensions according to biogeoclimatic conditions (Haeussler, 2011).
A general reduction of cell lumen in the north-south direction was observed, most likely as an adaptive strategy to face drought and reduce the risk of xylem cavitation. Similar trends are found among conifer species of arid (DeSoto et al., 2011) and mesic sites of Spain (Martin-Benito et al., 2013). On the other hand, larger tracheid dimensions with increasing drought severity have been reported for Pinus sylvestris in the Iberian peninsula (Martín et al., 2010) and in the Alps (Eilmann et al., 2009). While Martin-Benito et al. (2013) measured tracheid lumen areas µm2, as we did in this study, DeSoto et al. (2011), Martín et al. (2010), and Eilmann et al. (2009) based their conclusions on the radial diameter of cell lumen µm. According to the Hagen-Poiseuille law, capillary flow rate is proportional to the fourth power of the capillary radius, hence to the square of the conduit area (Tyree and Zimmermann, 2002). This implies a disproportionate effect of lumen size on transport, so that either cell diameter or even the average of cell lumen area, which are used in studying climatic influences on wood formation (Olano et al., 2012), underestimate flow rates under the Hagen-Poiseuille law (Sperry et al., 1994).
Narrower tracheids are considered more resistant to cavitation and more efficient for hydraulic conductivity under low water availability, thanks to their higher resistance to negative pressures (Hacke and Sperry, 2001; Sperry et al., 2006). Tradeoff mechanisms between hydraulic safety and structural effectiveness can be particularly complex (Tyree et al., 1994). For a given hydraulic conductivity, larger, thin-walled tracheids require a lower carbon investment in tissue production, thereby increasing the ability to tolerate water stress by reducing stomatal transpiration loss (Sperry, 2003). The reduction of both tracheid size and cell wall thickness at the southern sites and in the lower populations of PIMO and PIFL can be explained as a plastic response to drought (Bryukhanova and Fonti, 2013). Water stress occurring at lower elevations during the summer may be associated with the formation of “light rings” (Panayotov et al., 2013), which are characterized by thin-walled tracheids and reduced latewood proportions (Liang et al., 1997).
The small PILO tracheids probably reflect a prevailing genetic control on wood anatomy in this species. Their change even with a minor elevation shift (larger elements in Sna2 vs. Sna1) is consistent with preliminary observations on xylogenesis that suggest an earlier onset of cambial reactivation at the lower portion of the subalpine site (Ziaco et al., 2013). Compounding direct and indirect effects of both elevation and slope exposure could explain the larger dimension of tracheids found in PIEN on the eastern side of the Snake Range (Sna3). Based on NevCAN data, average April–June maximum temperature is 18.8°C at Sna3 and 14.9°C at Sna1–2; average April–June minimum temperature at both sites is −8.2°C. July–September rainfall accounts for about 35% of total annual precipitation at Sna3 vs. 20% at Sna1–2. Snow controls moisture availability at the Snake Range, and snowpack dynamics (e.g., timing of snowmelt) generally influence tree growth, especially at the beginning of the growing season. On the eastern flanks, higher spring temperature should anticipate snowmelt and the onset of xylem production (Rossi et al., 2011). Summer precipitation could extend the positive growth effects of the postmelting period further into the growing season, allowing the formation of larger cells. This particular climatic combination (warmer spring and moister summer) would create better growing conditions for PIEN, which in fact includes the largest individuals in our data set, particularly on the eastern flank of the Snake Range. The effect of tree size on anatomical features could be more pronounced in PIEN compared to other species included in this study, and therefore explain a larger proportion of tracheid characteristics (e.g., bigger lumen areas). Another species, PIFL, had larger tracheid lumen, diameter, and wall thickness at higher elevations in the Snake Range. Although such differences were not significant during 2000–2012, the most recent observations support this relationship (Ziaco et al., 2014).
Table 3.
F-statistic (with P value ≤ 0.005) from one-way ANOVA between mean chronologies by species of anatomical parameters for earlywood and latewood in the period 2000–2012 at the two sites where each species was present.
Earlywood features accounted for most of the intraspecific anatomical differences. Earlywood width (EW) was highly correlated with total ring width at all sites. In contrast, latewood width (LW) showed less or no correlation with annual ring width at the majority of sites. High correlations between earlywood and total ring width have been reported in conifer species from temperate (Liang et al., 2013), mesic (Martin-Benito et al., 2013), and dry sites (DeSoto et al., 2011). The weaker relationship between total ring and latewood width, in particular at the Sheep Range, is consistent with an intra-seasonal climatic control of latewood formation (Wang et al., 2002), associated to the summer pluviometric regime driven by the North American Monsoon System. The correlations between lumen area and width of earlywood and latewood in Great Basin conifers suggest that dimensional features linked to moisture conditions and stem water transport (lumen area) play an important role in determining radial growth.
Normalized time series of tree-ring parameters (EW and LW) and dimensional cell features show similar variations from 2000 to 2012, suggesting the presence of a common climatic signal responsible for a large part of the interannual variability of xylem hydraulic properties and tree-ring chronologies. The strength of such signal increases from earlywood to latewood, indicating a response to water availability during the summer (Bryukhanova and Fonti, 2013). The relationship between water availability and tree-ring features that emerged along elevation gradients for two species, PIMO and PIFL, was stronger for PIMO, so that the southern sites (in the Sheep Range) show a more pronounced gradient compared to the northern ones.
Wood cellular parameters varied in response to seasonal climate, providing insights on the mechanisms of tree-ring formation, and reflecting physiological adjustments to environmental constraints. An all-species analysis of average anatomical parameters against climate indicated significant relationships of precipitation and air temperature with wood anatomy, especially in the earlywood. Weak relationships between climate and average latewood parameters, with the possible exception of cell wall thickness, could be related to the limited variability of latewood cellular features between sites. Potentially many environmental factors (e.g., soil properties, radiative balance, snowpack dynamics) might have direct and indirect effects on growth and physiological processes that produce wood anatomy and tree-ring widths. Further research will use additional anatomical and climate data as they become available over time, as well as the information from automated point dendrometers and sap flow sensors that have been installed at the NevCAN sites (Mensing et al., 2013).
In conclusion, the NevCAN elevation transects in the Great Basin enable research on environmental controls of tree growth with unprecedented detail. Results reported here provide a glimpse of the potential applications that this new scientific tool could allow in the general field of botany. While the preliminary nature of our findings and the current brevity of NevCAN time series limit our general understanding of climate-growth relationships at the cellular level, we found that differences in water stress related to elevation lead to intraspecific modifications in the anatomical structure of tree rings. These changes are likely to occur at different elevations either because of precipitation or temperature influences, or through indirect pathways that control the maximum stem size, which then affects the anatomical parameters. Annual oscillations of tree-ring and anatomical parameters highlighted the presence of a common climatic driver at the intraspecific level. When no other distinctions are considered, temperature correlations with tracheid diameter seem more important than those with precipitation, but the role and interactions of confounding factors need to be further investigated. Accomplishing this task is within reach, given the ongoing research activities related to the availability of NevCAN observations expected in the future.
LITERATURE CITED
Notes
[1] The authors thank all the people and DendroLab personnel, especially S. Strachan, who have contributed, both in the field and in the laboratory, to the installation and maintenance of the NevCAN sensors. Permission to install and operate the NevCAN sensors at the Snake and Sheep Range was provided by the landowners, and we thank all private and public managers for their helpful cooperation. Greg McCurdy of the Desert Research Institute provided assistance with climatic data. This research was supported, in part, by the U.S. National Science Foundation under AGS-EAGER Grant No. 1256603. F.B. was further supported by a Charles Bullard Fellowship in Forest Research from Harvard University. The comments of two anonymous reviewers helped improve a previous version of the manuscript. The views and conclusions contained in this document are those of the authors and should not be interpreted as representing the opinions or policies of the funding agencies.
[2] 1 Latin names are from the International Plant Names Index (IPNI; http://www.ipni.org/index.html).