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Carbon partitioning in sugarcane internodal tissue with special reference to the insoluble fractionBindon, Keren (Keren Ann) 12 1900 (has links)
Thesis (MSc)--University of Stellenbosch, 2000. / ENGLISH ABSTRACT: The changes in carbon allocation to sucrose, hexoses, fibre, starch and respiration
were investigated in developing internodes of sugarcane. Radiolabelling studies were
conducted on internode 3, 6 and 9 tissue, representing three stages of increasing
maturity. It was apparent that a high rate of cycling between triose-phosphate and
hexose-phosphate occurred. A maximum of 50% of carbon entering triose-phosphates
was returned to hexose-phosphate in internode 3 tissue, and this flux decreased with
tissue maturity to 30%. Carbon partitioning into sucrose increased from 34% of total
14C uptake in internode 3, to 61% in internodes 6 and 9. In immature tissue, the
protein and fibre components were the dominant competing sinks with sucrose for
incoming carbon, to which 14 and 16% of carbon were allocated respectively.
Increased carbon allocation to sucrose with tissue maturity, coincided with a decrease
in partitioning to fibre. This indicated that previous studies had underestimated total
carbon allocation to respiration, since the protein component was not considered. In
contrast with earlier work, the respiratory pathway was the strongest competitor with
sucrose for incoming carbon, even in mature tissue. Between internodes 3 and 6,
carbon allocation to total respiration did not change significantly, but decreased 50%
in mature tissue. Starch was a weak competitor with sucrose, for incoming carbon, to
which a maximum of 2% of 14Cwas allocated in immature tissue. In cane harvested in
early spring, radiolabelled maltose was recovered in internode 3 tissue of ripening
cane, indicating that concomitant starch synthesis and degradation occurred. The.
redistribution of C-1 and C-6 in starch glucose was analysed following feeding of
tissue with [1_14C]_and [6_14C]_glucose. Randomization of label in starch indicated
that the pathway for carbon movement into sugarcane plastids for starch synthesis is
primarily through the triose-phosphate translocator. Finally, this study indicated that
radiolabelling of tissue discs is a suitable experimental system to determine carbon
flux in sugarcane. During the 3 h labelling period the rate of 14C02 release became
linear, indicating that the system approached isotopic steady state between the external
and internal glucose pool; and the respiratory processes involved in CO2 release. / AFRIKAANSE OPSOMMING: Die veranderinge in koolstoftoedeling na sukrose, heksoses, vesel, stysel en respirasie
is in ontwikkelende internodes van suikerriet ondersoek. Die koolhidraatmetabolisme
in internodes 3, 6 en 9, wat drie stadiums van toenemende rypheid verteenwoordig, is
met behulp van 14Cmerkingstudies ondersoek. Dit is duidelik dat daar 'n hoë mate van
koolstofsirkulering tussen die heksose- en triose-fosfaat poele voorkom. In internode 3
word tot 50% van die koolstofwat in triose-fosfate geïnkorporeer is, weer na heksosefosfaat
omgeskakel. Selfs in volwasse weefsel vind daar nog soveel as 30%
koolstofsirkukering plaas tussen die twee poele plaas. Koolstoftoedeling vanaf
glukose na sukrose het van 34% in internode 3, tot 61% in internodes 6 en 9
toegeneem. Proteïn en selwandkomponente was die belangrikste swelgpunte vir
koolstof in onvolwasse weefsel gewees. Namate die weefsel meer volwasse word,
word sukrose 'n belangriker swelgpunt. Die koolstoftoedeling aan sukrose is veral ten
koste van toedeling aan die selwandkomponente. Die bevinding dat die proteïenpoel 'n
sterk swelgpunt is dui aan dat vorige studies die belang van respiratoriese
koolstofvloei onderskat het. In teenstelling met vorige aansprake is dit duidelik dat
selfs in volwasse weefsel respirasie die grootste swelpunt vir die inkomende organiese
koolstof in die internode vorm. Koolstoftoedeling aan respirasie het nie
noemenswaardig tussen internodes 3 en 6 verskil nie, maar het met 50% in volwasse
weefsel afgeneem. Stysel is deurgaans 'n swak swelgpunt vir koolstof met die hoogste
toedeling aan die poel (2%) in die jong weefsel (internode 3) . Na toediening van [U-
14C]-glukose is radioaktief gemerkte maltose gevind in suikerriet wat vroeg in die
lente geoes is. Dit dui aan dat gelyktydige afbraak en sintese van stysel plaasgevind
het. Die herverdeling van C-l en C-6 in glukose afkomstig van stysel is na toediening
van [1_14C]_ en [6-14C]-glukose ontleed. Die ewekansige verspreiding van
radioaktiwiteit tussen koolstof 1 en 6 van die glukose in stysel dui aan dat dit
hoofsaaklik die triose-fosfaat translokeerder is wat in die plastied verantwoordelik is.
Hierdie studie het ook aangetoon dat radioaktiewe merking van weefselsnitte 'n
geskikte eksperimentele sisteem is om koolstoftoedeling in suikerriet te ondersoek.
Die patroon van 14C02 vrystelling dui daarop dat die weefsel na 'n 3 h
inkuberingsperiode isotopiese ewewig tussen die eksterne en interne glukose poele en
die respiratoriese prosesse begin bereik het.
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INFERENCE OF PAST ATMOSPHERIC DELTA CARBON-13 AND ATMOSPHERIC CARBON-DIOXIDE FROM CARBON-13/CARBON-12 MEASUREMENTS IN TREE RINGS.LEAVITT, STEVEN WARREN. January 1982 (has links)
Carbon dioxide release from fossil-fuel burning is significant enough that we may soon experience perceptible changes in climate with important human consequences. Man's activities involving deforestation and agriculture have undoubtedly also affected atmospheric CO₂, although quantitative, and even qualitative, net effects of these processes are incompletely understood relative to fossil-fuel production. An accurate reconstruction of past ¹³C/¹²C ratios of atmospheric CO₂ may provide key constraints on the historical activity of the biosphere as CO₂ source or sink. Tree rings appear to be a repository of this information but there is much noise in the collection of previous reconstructions, presumably associated with site selection, radial variability, choice of representative wood chemical constituent, and subtle effects of climate on fractionation. This study attempts to avoid these pitfalls and develop a 50-yr δ¹³C(ATM) record from juniper trees (genus Juniperus), in fact, by taking advantage of the influence of climate on fractionation. Trees were harvested from suitable sites in close proximity to weather stations with monthly records of temperature and precipitation. Ring material was then separated from each of the sections in 5-yr intervals from 1930 to 1979 around their full circumference, and cellulose was extracted from the wood. After measuring δ¹³C of the cellulose by standard mass-spectrometric techniques, a variety of δ¹³C vs. climate functions were examined for each interval. The most useful relationships for at most 7 of the 10 sites were δ¹³C with December temperature or precipitation, because the coefficients were nearly constant from one interval to the next (averaging -0.27%₀ °C⁻¹ for temperature and -0.04%₀ mm⁻¹ for precipitation) and the intercepts differed. Local pollution effects are believed responsible for the three anomalous sites. The separation of these regression lines of different intervals is interpreted as the response of the trees to the changing δ¹³C of atmospheric CO₂ so that δ¹³C(ATM) curves are constructed from this spacing. The shape of the best-fit reconstruction suggests the biosphere has acted as CO₂ source to about 1965 and may now be a net sink. Although these conclusions are limited by certain assumptions and statistical restrictions, evidence from the recent scientific literature tends to support the increasing role of the biosphere as an important carbon sink.
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Interactions between atmospheric nitrogen deposition and carbon dynamics in peatlandsCurrey, Pauline M. January 2009 (has links)
Most undisturbed peatlands sequester carbon, and rising levels of atmospheric nitrogen deposition may have the potential to destabilize this function, possibly resulting in an increased release of carbon dioxide into the atmosphere. It is therefore of vital importance to investigate further the link between atmospheric nitrogen deposition and carbon dynamics in exposed ecosystems such as peatlands. The work described in this thesis aimed to elucidate the impact of increasing nitrogen on aspects of carbon turnover in peatlands. Using a long-term field-based experiment, I tested the effects of 4 years of ammonium and nitrate addition (8, 24 and 56 kg N ha<sup>-1</sup> y<sup>-1</sup>) on the fate of newly photosynthesised carbon by plants and the turnover of labile and recalcitrant carbon. A second set of experiments undertaken in the laboratory assessed the use of plant wax analysis as potential biomarkers of past changes in vegetation and carbon status in peat. Overall, this work has shown that the form of nitrogen (ammonium versus nitrate) is a crucial component of atmospheric pollution and must be taken into consideration when investigating or predicting effects of reactive nitrogen on peatlands. In addition, nitrogen addition affected the fate of newly synthesised carbon differently in <i>Eriophorum vaginatum </i>and <i>Calluna vulgaris, </i>revealing the importance of considering plant traits when investigating environmental changes in terrestrial ecosystems. Furthermore, it has led to the development of an investigative tool for further exploration of the historical effects of atmospheric nitrogen deposition on vegetation an carbon content in peatlands.
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Plant diversity, physiology, and function in the face of global changePrager, Case Mahone January 2017 (has links)
One central goal in ecology is to understand how biodiversity, and key organismal traits, interact with ecosystem properties and processes, and ultimately to understand and predict how these interactions will be affected by rapid environmental change. Thus, global change experiments and observational gradients in diversity provide the opportunity to examine and test hypotheses about how organismal traits, multiple dimensions of biodiversity, and ecosystem function will respond to environmental change. In Arctic tundra, increased nitrogen (N) and phosphorus (P) availability accompanying rapid warming is thought to significantly alter plant community composition and ecosystem function. The following four chapters examine hypotheses about the responses of species’ traits, multiple dimensions of biodiversity, and ecosystem function to the effects Arctic warming. Chapter 1 examines plant community composition and the capacity for ecosystem function (net ecosystem exchange, ecosystem respiration, and gross primary production) across a gradient of experimental N and P addition expected to more closely approximate warming-induced fertilization, demonstrating declines in plant diversity and an increase in the capacity for ecosystem carbon uptake at the highest level of fertilization. Chapter 2 examines a set of physiological and functional leaf traits across the same N and P gradient in order to evaluate the possible physiological mechanisms underlying community and ecosystem responses, highlighting the effects of increasing nutrient availability for deciduous shrub species. Chapter 3 found that single-dose, long-term nutrient addition (i.e., > 20 years) led to significant declines in multiple dimensions of diversity (taxonomic, functional and phylogenetic), and that these effects persist through time, increasing for dimensions that capture organismal traits (functional and phylogenetic). Finally, Chapter 4 examined the relationship between multidimensional diversity and ecosystem function across a natural gradient of diversity, and found that taxonomic diversity and functional diversity were significantly and positively related to whole ecosystem productivity, and, conversely, functional evenness and dispersion were significantly and negatively related to ecosystem productivity. Cumulatively, these four chapters advance our understanding of the connections between communities and ecosystems in a rapidly changing ecosystem.
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Pathways, patterns and dynamics of dissolved organic carbon in a temperate forested swamp catchmentDalva, Moshe January 1990 (has links)
No description available.
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Carbon and energy exchange of semi-arid ecosystems with heterogeneous canopy structureAnthoni, Peter M. 20 October 1999 (has links)
Carbon and energy fluxes were measured with the eddy covariance technique
above two semi-arid ecosystems, ponderosa pine and juniper/sagebrush, located in
central Oregon. The two ecosystems have low LAI and a very open canopy structure.
The energy closure was ~70-80% at both ecosystems, equivalent to an imbalance of
150-250 W m⁻² on cloudless summer days, when net radiation (R[subscript n]) was ~600-700 W
m⁻². The lack of closure cannot be explained by the uncertainty of an estimate of
available energy due to a single R[subscript n] sensor location. At the more open
juniper/sagebrush ecosystem, a numerical model showed that spatial variation in R[subscript n],
even for large differences in surface radiation temperature and reflection coefficient
between ecosystem components (soil and vegetation), is less than 10% of measured
R[subscript n]. The uncertainty in R[subscript n] at the two-layered ponderosa pine ecosystem with patches
of young and old-growth trees is expected to be smaller than at the juniper ecosystem.
Net carbon exchange (NEE) at the pine site strongly depends on environmental
factors effecting carbon assimilation (A[subscript c]) and ecosystem respiration (R[subscript e]). A more
detailed analysis of the carbon budget showed a strong negative response of carbon
uptake to large vapor pressure deficits (VPD), whereas water vapor exchange (LE)
was less affected. At large VPD the vegetation maintains a sustainable water flow
through the soil-plant system by stomatal control of transpiration. The stomatal
closure leads to limitation in A[subscript c], but LE is subject to a positive feedback from higher
evaporative demand.
Annual NEE of the ponderosa pine forest (200-300 gC m⁻²) was in the mid-range
of reported NEE of temperate forest ecosystems, though, unusually, much of the
annual carbon gain occurred during the fall through spring, because the relatively mild
winters allowed carbon assimilation to occur and R[subscript e] rates were low.
The information gathered at our ponderosa pine site during two years with
contrasting climate suggests that the carbon uptake of the ponderosa pine ecosystem
will be more sensitive to global climate change than the water vapor exchange. / Graduation date: 2000
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Linking soluble C to microbial community composition and dynamics during decomposition of ����C-labeled ryegrassMcMahon, Shawna K. 13 January 2004 (has links)
Ryegrass residue consists of three main C fractions: readily available soluble C,
intermediately available cellulose and hemicellulose, and slowly available lignin.
Changes in chemical composition during decomposition influence rate of degradation as
well as composition of the microbial community involved. Use of ����C-labeled plant
material coupled with analysis of phospholipid fatty acids (PLEA) by isotope ratio mass
spectrometry results in a powerful tool for linking microbial community structure and C
cycling processes during decomposition.
The objective was to investigate the role of soluble C in the decomposition of
ryegrass straw. We wanted to determine (i) if the presence or absence of labile C in straw
affects C mineralization by the microbial community, (ii) if community structure would
differ based on the presence of labile C, and (iii) if community structure would shift as
decomposition progressed.
Residue was added to soil microcosms at rates that reflect field loads. Treatments
were unleached straw (US), leached straw (LS), and leachate (L), plus an unamended
control (C). Added substrates had ������C values between 120% and 180% the native soil
signature was 26%. Respiration was measured every 4 to 6 hours for the first 5 d, and
weekly thereafter. Destructive sampling took place after 0.6, 1 .6, 1 5, 1 8. 50, and 80 d of
incubation and microbial biomass '��C (MBC) and PLFAs were analyzed.
The soluble component of ryegrass straw strongly influenced C mineralization
and assimilation, as well as microbial community composition and dynamics. CO2
evolution rates and ����C signatures were similar in US and L during the first 3 d of
incubation. Most soluble C from leachate was consumed during that time, indicated by
the rapid decrease in ������C value of CO2 evolved from L treatment. Substrate-derived C
moved quickly into and through the microbial biomass.
Distinct temporal shifts occurred in community composition. Early communities
in amended soils were dominated by short and branched-chain PLFAs such as 15:Oa.
Later samples contained more complex and longer PLFAs. 19:Ocy was an indicator for
late succession communities in US and L, and 18:2w6,9 characterized late samples in LS.
Soluble C affected when the temporal shift occurred in LS and L, communities shifted
earlier than in US. Lipids were differentially enriched with ����C. Fungi, as indicated by
18:2w6,9, were more effective at incorporating substrate C into cellular lipids, as this was
the most highly labeled of all PLFAs. / Graduation date: 2004
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NMR study of 1,4-phenilene-bis(dithiadiazolyl), soil organic matter and copper aluminum oxideMonte, Francesca 06 January 2000 (has links)
Graduation date: 2000
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Biogeochemistry and hydrology of three alpine proglacial environments resulting from glacier retreatBruckner, Monica Zanzola. January 2008 (has links) (PDF)
Thesis (MS)--Montana State University--Bozeman, 2008. / Typescript. Chairperson, Graduate Committee: Mark L. Skidmore. Includes bibliographical references.
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Numerical modelling of climate and the carbon cycle during the CenozoicRoberts, Chris David January 2011 (has links)
No description available.
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