How Thickness of Chlorophyll in Aspen Bark is dependent on Height and Stand type. Lizabeth Rodriguez...
-
Upload
rachel-merry-warren -
Category
Documents
-
view
213 -
download
0
Transcript of How Thickness of Chlorophyll in Aspen Bark is dependent on Height and Stand type. Lizabeth Rodriguez...
How Thickness of Chlorophyll in Aspen Bark is dependent on
Height and Stand type.
Lizabeth Rodriguez Winter Ecology Spring 2014
CU Mountain Research Station
Introduction
It is important to understand where the chlorophyll is located within the bark and what affects it, because it is how Aspen can survive, and compete with conifers. -Bark can provide up to 15% of the photosynthetic surface of a tree (Schaedle and Foote 1971).
Anatomy:• Lenticels are breaks in the outside of the bark that are used for gas exchange, however they
can not make up for the loss of stomata and carbon recycling must occur (Aschan et al. 2001)
• Outside of the bark is called the periderm
• Under the periderm is the cortex which contains chloroplasts. • Layer of chloroplast containing cells is called Chlorenchyma (Aschan et al 2001)
• Chloroplast density dramatically decreases with depth (Schaedle et al. 1968)
(Populus tremuloides michx.)
Previous studies • Temperature (Schaedle and Foote 1971)
• Some bark photosynthesis occurs well below 0 degrees• Rate of photosynthesis increases drastically between 10-25 degrees
• Elevation (Covington 1975)• Trees appeared greener at higher elevations and more white at low elevations
due to dead peridem build up • Chlorophyll content of bark decreases as altitude increases
• Age (Aschan et al 2001)• Chlorophyll content decreases with age
• None have considered height.
Since the top of trees get more sun, does the bark higher up on aspen trees have more or less chlorophyll when compared to lower levels?
Hypothesis: There will be a thinner layer of chlorenchyma cells in bark that is at a shorter height; less light penetrates lower, especially underneath the snow therefore is not useful for the tree to spend energy up keeping a large amount of photosynthetic cells at lower heights.
Null: The chlorenchyma layer will be a similar thickness throughout each tree
Does stand type (aspen only vs mixed with conifers) effect chlorophyll thickness?
Hypothesis: Conifer trees shade the area, so aspens in mixed stands will need a thicker chlorenchyma to be able to produce as much glucose as aspens in stands that have no conifers.
Field • Five 2x2m plots were sampled • No sapling tissue was collected• For each Aspen, three bark samples were taken according to height above the soil
• 225cm • 155cm • 30cm - underneath a significant amount of snow in every case.
• All samples are from the south side of the tree and stored in Zip-lock bags to minimize oxidation damage and drying out overnight.
30 m 155 225 Lab• Cross section slices
were observed under a compound microscope, and a photograph was taken
• Length measurements were made using AxioCam software • multiple
measurements were made for each image and averaged for each tree.
Data Analysis • Unpaired T-tests and a
Two way anova were ran using R
P-value: 0.014 P-value: 0.598
• There was a general trend of increasing chlorenchyma thickness with height
• Unpaired T-Tests were performed. • There is a 59.89% chance there is no difference between 225 and 155• There is only a 1.41% chance there is no difference in chlorophyll thickness between 30
and 155
Results
Results separated by plot
1 2 3 4 50
0.5
1
1.5
2
2.5
3
How Thickness of Chlorophyll inside Aspen Bark Changes with different heights
30155225
Plot Number
Thic
knes
s of C
hlor
ophy
ll la
yer (
mm
)
• The correlation between height and chlorophyll thickness is strong in plots 1, 4 and 5• 2&3 do not follow this pattern, these plots were noticeably sunnier and located in the
aspen grove where no conifers were growing
2nd Question: Does stand type (aspen only vs mixed with conifers) effect chlorophyll thickness?
• F-value = mean of squares /mean residual variance (unexplainable error)• Larger F-value means more significance
• Inversely related to P-value
• How thickness is affected by• Height F=19.323 -what I looked at during t-test
• P=7.637e-05• Stand type F=27.793
• P=4.658e-06• Mean thickness in plots 1,4&5 compared to mean thickness in plots 2&3
• Interaction between height and stand type F=20.235
• P=5.539e-05
Two way ANOVA-Thickness vs Height and Stand type
In mixed stands there is a larger range of thickness between the heights, a different pattern of thickness depending on stand type.
Summary of results
• There was a general trend of increasing chlorenchyma thickness with height, this increase was especially evident between the below snow samples and the above snow samples .
• Aspen only stands have thinner chlorenchyma layers than Aspen trees that are mixed in with conifer trees
• In mixed stands there is a larger range of thickness between the heights, while aspen only stands do not have much variation , they exhibit a different pattern.
• Strong reflection off of the snow explains why in plot number 3 the 155cm height was strongest.
Plot 2 and 3 in Aspen grove (no conifers) - Discussion
• The 30cm height is not thinner, in this area because enough sunlight reaches through the snow to the bark allowing enough photosynthesis to occur
• offsets the energy cost of maintaining the specialized chlorophyll cells.
Hypothesis: Conifer trees shade the area, so aspens in mixed stands will need a thicker chlorenchyma to be able to produce as much glucose as aspens in stands that have no conifers.
Discussion – summary
• The null hypothesis was rejected, the alternate hypothesis that Aspen trees do not have as much use for chlorophyll underneath the snow is supported.
• However, in Aspen only stands enough sunlight penetrates the snow and reaches the bark, at 30cm off the ground, allowing enough photosynthesis to occur to offset the energy cost of maintaining the specialized chlorophyll cells. • Second null hypothesis was rejected, a difference between stand types was
seen.
• Although rate of photosynthesis is increased in temperatures above zero, the insulation from the snow does not mean increased photosynthesis, because of the lack of available sunlight.
Further Research• Do fungal infections effect how well Aspens
photosynthesize?• Hypothesis: Parasitic fungi steal nutrients
and energy from plants, aspen trees that are victim s of a fungal infection will have a difference in chlorenchyma layer thickness when compared to healthy, uninfected trees
• Does the pattern of thicker chlorenchyma with increased height also apply to saplings?
Acknowledgements
• Thanks to Tim Kittel for data processing help • Derek Sweeney for field equipment • And Stephanie Meyer for letting me use her
lab and microscope equipment
Literature cited:
Aschan, G., Wittmann, c. &pfanz, H. (2001). Age-dependent bark photosynthesis of aspen
twigs, Trees-Structure and Function, 15, 431-437
Covington, Wallace W. (1975) Altidudinal Variation of Chlorophyll Concentration and
Reflectance of the Bark of Populous tremuloides. Ecology, 56, 715-720
Pearson, L.C. & Lawrence, D.B. (1958). Photosynthesis in Aspen Bark. American Journal of
Botany, 45, 383-387.
Schaedle, M. & Foote, K.C. (1971). Seasonal Changes in Photosynthetic Capacity of Populus
Tremuloides Bark. Forest Science, 17, 308-&.
Schaedle, M., Iannacco.P & Foote, K.C. (1968). Hill Reaction Capacity of Isolated Quaking
Aspen Bark Chloroplasts. Forest Science, 14, 222-&.
Apendix – R console, script