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Original Article 

Biosci. J., Uberlândia, v. 34, supplement 1, p. 17-27, Dec. 2018 

QUANTITATIVE ANALYSIS OF JATROPHA GROWTH: MICRONUTRIENT 

DELIVERY SYSTEM AND NPK COMBINED EFFECTS 

 
ANÁLISE QUANTITATIVA DE CRESCIMENTO DO PINHÃO MANSO: EFEITOS 

COMBINADOS DE UM SISTEMA DE FORNECIMENTO DE MICRONUTRIENTES E 
NPK 

 

Alexandre Bosco de OLIVEIRA
1
; Wagner VENDRAME

2
; Anne Pinheiro COSTA

3
;  

Luciana C. N. LONDE
4 

1. Department of Crop Science, Federal University of Ceará, Campus do Pici, Bloco 805, Fortaleza, CE, Brazil; 2. Tropical Research 
and Education Center, University of Florida, Homestead, FL, USA; 3. Faculty of Agronomy and Veterinary Medicine, University of 

Brasilia, Campus Darcy Ribeiro, Brasilia, DF, Brazil. annecosta@gmail.com; 4. Experimental Field in Gorutuba, Agricultural Research 
Company of Minas Gerais (Epamig), Nova Porteirinha, MG, Brazil. 

 

ABSTRACT: Studies approaching jatropha (Jatropha curcas L.) growth through quantitative analysis 
parameters are limited, especially regarding the response to different fertilizer types and doses. In order to investigate the 
effects of a micronutrient delivery system (MDS) fertilizer, a full quantitative analysis of growth in jatropha young plants 
was performed, comparing this system effectiveness under different NPK doses. Plants were grown in 3.9 L pots 
containing local soil, with or without MDS (main plot), combined with NPK doses (0; 1.8; 4.7 and 7.4 g L-1) in subplots. 
Dose-response curves of quantitative analysis variables were generated for three periods of time (40, 80 and 120 days after 
sown) as a sub-subplot. Quantitative analysis of growth showed that most parameters evaluated in this study were 
improved by MDS application, resulting in benefits for jatropha initial development, regardless of NPK doses. Even 
without NPK supplementation or under the lowest dose evaluated (1.8 g L-1), MDS provided better growth of J. curcas 
plants, being usually equivalent to the highest doses of NPK (4.7 and 7.4 g L-1) without MDS. The effective response of 
jatropha young plants to MDS supplementation indicates that this kind of fertilizer played a relevant role in the species 
metabolism, resulting in faster growth and enhanced biomass allocation. 
 

KEYWORDS: Bioavailable mineral nutrients; Micronutrient fertilizer; Jatropha curcas L.; Biomass allocation; 
Ecophysiology. 
 

INTRODUCTION 
 
Growth, survival and reproduction are the 

three imperatives of any organism, and in plants, 
growth is particularly important because both 
survival and reproduction depend on plant size and 
therefore on growth rate (SHIPLEY, 2006). Poorter 
et al. (2012) emphasize that the relative amount of 
biomass present in the various organs, namely 
‘biomass allocation’, is not fixed but may vary over 
time, across environments and among species. 
Therefore, a quantitative understanding of such 
patterns has many uses in agricultural practice and 
implementation, as these patterns, and the extent to 
which they vary among species, set limits on 
biomass production and utilization (REICH, 2002; 
OLIVEIRA et al., 2011; POORTER et al., 2012; 
BELTRÃO et al., 2016). 

A quantitative analysis of plant growth is 
based on estimation of quantitative variables to 
provide a description and analysis of the biomass 
allocation to the different plant organs, which at any 
given time is a strong driver of the plant’s capacity 
to take up carbon, water and nutrients for future use 
(EVANS, 1972; POORTER, 2012). Souza et al. 

(2016) explain that among the estimates in a 
quantitative analysis of plant growth, it is possible 
to determine: the “absolute growth rate” as being the 
increase in plant phytomass in any one period; the 
“relative growth rate” as representing the amount of 
plant material produced by a given amount of 
existing material (g) over a time interval (days); and 
the “net assimilation rate” as an assessment of the 
leaf size, which is involved in the production of dry 
matter (BEADLE, 2014). 

Jatropha (Jatropha curcas L.) is considered 
an important tropical biofuel plant. It is claimed that 
this species can be grown on soils with low nutrient 
content, but Negussie et al. (2016) have revealed in 
their recent study that yield is significantly low in 
non-fertilized trees. In contrast, for Lima et al. 
(2016), jatropha is a perennial species that requires 
expressive amounts of nutrients to produce 
satisfactorily. These authors observed that 
phosphate fertilization associated with organic 
fertilization significantly influenced plant height, 
number of branches, stem diameter, leaf area, 
number of seeds per plant and total mass of seeds. 

Studies involving the use of micronutrients 
in jatropha are even more limited. However, studies 

Received: 20/09/17 
Accepted: 15/06/18 



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Quantitative analysis of jatropha…   OLIVEIRA, A. B. et al. 

Biosci. J., Uberlândia, v. 34, supplement 1, p. 17-27, Dec. 2018 

of micronutrient fertilization using micronutrient 
delivery system (MDS) fertilizers as a source of Cu 
and Zn could be beneficial for jatropha crop 
production. Copper is a vital component of electron 
transfer reactions mediated by cytochrome c oxidase 
and plastocyanin (YRUELA, 2005), whereas zinc 
increases the biosynthesis of chlorophyll and 
carotenoids (BROADLEY et al. 2007). Optimum 
Cu and Zn concentrations positively affect the 
development of the membrane system of 
chloroplasts and chlorophyll content (AHMAD et 
al., 2015). 

Although many studies have been 
performed evaluating jatropha initial growth and 
development, most of them did not approach the 
plant growth through quantitative analysis 
parameters, especially regarding the response to 
different fertilizer types and doses. This type of 
investigation not only provides relevant insights on 
ecophysiological changes that occur in crops during 
their development (basic science) but also allows 
researchers and companies to use this information 
pool to recommend the most efficient fertilizer 
combinations for each crop (applied science). 
Therefore, the objective of the present study was to 
evaluate the effects of a micronutrient delivery 
system (MDS) fertilizer through a quantitative 
growth analysis of jatropha young plants, comparing 
this system effectiveness under different NPK 
doses. 
 
MATERIAL AND METHODS 

 

Location, plant material, and experimental 

conditions 
Seeds originated from 12 jatropha 

accessions from India were selected for the trials. 
Both seeds and soil used in this study were collected 
from a jatropha collection field plot at University of 
Florida's Tropical Research and Educational Center 
(TREC) (25°50′N and 80°50′W, 3.8 m above sea 
level), in Homestead, FL, USA.  

Soil analysis was performed by A&L 
Southern Agricultural Laboratories (Deerfield 
Beach, FL). The soil is classified as a Krome very 
gravelly loam, being very shallow, well-drained 
with limerock up to the soil surface, pH 7.4 to 8.4, 
low water holding capacity, 3% to 10% organic 
matter content, cation-exchange capacity 8.7–12.2 
meq 100g-1, and low nutrient content (LI, 2001). 
Elements including Mg, Zn, Mn, and Fe, although 
present in the soil profile, are unavailable for plant 
uptake (CRANE et al., 2010). 

The experiment was performed from 
October 2016 to January 2017 in a greenhouse (19.6 

- 25.8° C; 31 - 86% average minimum/maximum 
temperature and air relative humidity, respectively), 
using 3.9 L plastic black pots filled with local soil. It 
consisted on the evaluation of the effects of a new 
commercial fertilizer (BAM-FXTM Bio-Available 
Minerals; Zero Gravity Solutions Inc, Boca Raton, 
FL, USA) that delivers balanced minerals into plant 
tissues (bioavailable mineral nutrients), known as 
MDS. According to the manufacturer, this is a 
highly positively charged cationic Zn2+ and cationic 
Cu2+ solution balanced together in a specific ratio, 
along with sulfate and ammonium. The laboratorial 
analysis carried out by Thornton Laboratories 
Testing & Inspection Services, Inc. (Tampa, FL) 
reported 2.03% Cu, 7.14% Zn and a redox potential 
of 484.4 mV. T For treatments using the product, 
applications followed label recommendations; by 
soil drench (125 mL L-1) immediately before sown, 
and by foliar application (62.5 mL L-1) at 40 and 80 
days after sown (DAS). 

The NPK source included different doses of 
a commercial NPK fertilizer formulation 15-9-12 
(Osmocote® Plus, Dublin, OH, USA) according to 
low, medium and high incorporation rates suggested 
on the product label, resulting in 1.8, 4.7 and 7.4 g 
L-1 of container, respectively. The fertilizer 
manufacturer sheet provided a guaranteed analysis 
report including N 15%, P2O5 9%, K2O 12%, Mg 
1.3%, S 5.9%, B 0.02%, Cu 0.05%, Fe 0.46%, Mn 
0.06%, Mo 0.02% and Zn 0.05%. 
 
Experiment establishment design and 

characteristics evaluated 
Six jatropha seeds were sown per pot at the 

beginning of this study. Germination and vigor of 
seedlings were evaluated during the first 10 DAS. 
Seedlings with poor vigor were removed to maintain 
the three most vigorous seedlings for each pot. 
Plants were irrigated using an automatic sprinkler 
irrigation system twice a day. Pesticide application 
was not necessary in this study. 

Prior to each MDS foliar application (40 
and 80 DAS), as well as in the final assessment of 
this study (120 DAS), one plant from each pot was 
randomly selected and removed to measure the 
growth characteristics and estimate growth 
variables. Leaf chlorophyll index was measured on 
three newly maturated leaves with a SPAD 502 
meter (Konica Minolta Sensing, Osaka, Japan). 
Plants were then harvested, all leaves were removed 
and the total leaf area per plant (LA) was 
determined with a leaf area meter (Li-Cor, Lincoln, 
NE; model Li-3000). Plants were uprooted 
carefully, and roots were washed with tap water to 
remove soil attached to the root system. Plant 



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tissues were then oven-dried at 80°C for two days, 
and leaf (LDW), stem (SDW) and root (RDW) dry 
weight were determined. We used this data to 
calculate the shoot (SDW), root (RDW), and plant 
dry weight (PDW). 

For quantitative analysis of jatropha growth, 
the following parameters were used: root dry 
weight/shoot dry weight ratio (RDW/SDW), leaf 
area ratio (LAR), leaf weight ratio (LWR), specific 
leaf area (SLA), leaf area index (LAI), absolute 
growth rate (AGR), relative growth rate (RGR) and 
net assimilation rate (NAR).  

Growth indices were calculated according to 
the following formulas (EVANS, 1972; BEADLE, 
2014; SOUZA et al. 2016): 
RDW/SDW (dimensionless) = RDW/SDW (ratio of 
root dry mass to shoot dry mass in grams). 
LAR (dm2 g-1) = LA/PDW, where LA and PDW are 
leaf area and plant dry weight respectively. 
LWR (dm2 g-1) = LDW/PDW, where LDW and 
PDW are leaf and plant dry weight respectively. 
SLA (dm2 g-1) = LA/LDW, where LA and LDW are 
leaf area and leaf dry weight respectively. 
LAI (dimensionless) = RGR * (LA/PDWf), where 
RGR is the relative growth rate, LA and PDWf are 
the leaf area and plant dry weight at the end of each 
harvest. 
AGR (g day-1) = (PDWf - PDWi)/(tf - ti), where 
PDWf and PDWi are the plant dry weight at the 
start and the end of the experiment, tf and ti 
correspond to the final and initial period. 
RGR (g g-1 day-1) = (lnPDWf - lnPDWi)/(tf - ti), 
where lnPDWf and lnPDWi are the natural 
logarithms for plant dry weight at the start and end, 
(ti and tf correspond to the period in days). 
NAR (g cm-2 day-1) = [(PDWf - PDWi)/(LAf - LAi)] 
* [(lnLAf - lnLAi)/ (tf - ti)], defined as the ratio 
expressed by the difference between the final and 
initial dry weight (PDWf and PDWi) and final and 
initial leaf area (LAf - LAi), as well as the ratio of 
the difference between the natural logarithm of the 
final and initial leaf area (lnLAf - lnLAi) and of the 
period (tf - ti). 
 
Statistical design and data analysis 

Six replicates of three plants were used for 
each treatment. Treatments were arranged in a split-
split plot design assessing different MDS and NPK 
combinations throughout time. The absence or 
presence of MDS was placed in main plot, and the 
NPK doses (0; 1.8; 4.7 and 7.4 g L-1) in subplot. 
Dose-response curves of quantitative data were 
generated for three periods of time (40, 80 and 120 
DAS) as a sub-subplot. 

Dose-response relationships were assessed 
by adjustment of simple and multiple linear 
regression models used to predict growth 
responsiveness as a function of various MDS and 
NPK combinations. The fits of different regression 
models were compared through analysis of variance 
by F test at 5% probability. Among the regression 
models tested (linear and quadratic), the one with 
the highest coefficient of determination was defined 
for each set of variables, whose parameter 
estimators of the equation were significant to at least 
5% probability. All calculations and graphs were 
performed using the Prism 7 analysis software 
(GraphPad Software, Inc.). 
 
RESULTS 

 

Biomass production and allocation 
In jatropha, the deviations from the linear 

regression due to 'lack of fit' were not significant 
when compared with the within-sample variation 
(Figures 1, 2, 3 and 4). Therefore, with only two 
exceptions, the set of data evaluated in this study 
using linear regressions relating MDS and time with 
NPK were adequate. 

Both shoot and root development improved 
with MDS application, even with no NPK 
supplementation in the soil (Figures 1A and 1B). At 
the end of the experiment (120 DAS), higher 
discrepancies were observed among the treatments, 
confirming that frequent MDS applications provided 
better results than high incorporation of NPK before 
sown. Furthermore, for this linear regression, there 
is a decrease in both SDW and RDW values 
inversely proportional to NPK dose increments, 
which infers deleterious effects of higher NPK 
doses and MDS application. This is probably 
because of the large amount of soluble salts 
incorporated into the soil. As expected, a similar 
behavior was observed for SDW/RDW, since these 
three variables were highly correlated to each other 
(Figure 1C). Therefore, MDS application not only 
provided a better initial growth of jatropha plants, 
but also enhanced the biomass allocation for roots, 
resulting in improved uptake of water and nutrients 
by the plants. 
 

Leaf area, chlorophyll, and source-sink relations 
Jatropha leaf area increased in direct 

proportion to NPK doses, with the data adjusted to 
linear regression model, except at 40 days with no 
MDS fertilizer application, which was better 
adjusted to a quadratic regression model (Figure 
2A). Although we observed similar increments for 
chlorophyll index (SPAD values) in leaves from 



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plants growing without MDS fertilizer applications, 
there were practically constant linear regressions for 
the other group of plants (treated with MDS) 
regardless of the NPK doses (Figure 2B). 

Most values obtained for LAR and LWR 
were similar to each other and did not differ among 
plants treated and not treated with MDS fertilizer, 

with most of them better adjusted to linear 
regression models (Figures 2C and 3A). These 
variables showed low or no variation as a function 
of NPK doses, with more noticeable increment 
observed for LWR in plants not treated with MDS at 
120 DAS (Figure 3A). 

 

 
Figure 1. Shoot dry weight, SDW (A); root dry weight, RDW (B); and root dry weight/shoot dry weight ratio, 

RDW/SDW (C) in 40, 80 and 120 day-old Jatropha curcas L. plants due to fertilization with a 
micronutrient delivery system (MDS) and different doses of NPK. 

 
Unlike most variables analyzed in this 

study, SLA presented higher values for plants not 
treated with MDS, which values reduced at 40 and 
120 DAS, and slightly increased at 80 DAS, due to 
NPK doses increment (Figure 3B). Nonetheless, we 
observed inverse behavior for LAI linear regression 

models, with low values observed for all treatments 
under 0, 1.8 or 4.7 g L-1 of NPK, however with 
significant increases in plants growing under MDS 
applications and 7.4 g L-1 of NPK, mainly at 80 
DAS (Figure 3C). 

 



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Figure 2. Leaf area (A); chlorophyll index (B); and leaf area ratio, LAR (C) in 40, 80 and 120 day-old 

Jatropha curcas L. plants due to fertilization with a micronutrient delivery system (MDS) and 
different doses of NPK. 

 



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Figure 3. Leaf weight ratio, LWR (A); specific leaf area, SLR (B); and leaf area index, LAI (C) in 40, 80 and 

120 day-old Jatropha curcas L. plants due to fertilization with a micronutrient delivery system 
(MDS) and different doses of NPK. 

 
Quantitative growth analysis estimative 

In the present study, AGR, RGR, and NAR 
variables presented similar behavior, with most data 
adjusted to linear regression models, except for 
RGR curve at 120 DAS in plants treated with MDS 
fertilizer, which the data fitted a quadratic model 
regression (Figure 4). Like other variables 
previously mentioned, MDS fertilizer application 

resulted in higher values for these growth estimates 
in plants with no or low (1.8 g L-1) NPK 
supplementation. This was clearly emphasized on 
regressions of 120-day-old jatropha plants, in which 
these parameters were inversely proportional to 
NPK doses, whereas the other regression lines 
resulted in slightly increases due to higher NPK 
incorporation into the soil. 

 
 



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Figure 4. Absolute growth rate, AGR (A); relative growth rate, RGR (B); and net assimilation rate, NAR (C) in 

40, 80 and 120 day-old Jatropha curcas L. plants due to fertilization with a micronutrient delivery 
system (MDS) and different doses of NPK. 

 

DISCUSSION 

 

Biomass production and allocation 
Faster growth, higher biomass production, 

and better RDW/SDW ratio were observed in plants 
treated with MDS fertilizer, representing some of 
the major benefits of bioavailable mineral nutrients 
uptake by jatropha young plants. As a primary 
source of Zn and Cu through soil drench and foliar 
applications in the present study, MDS fertilizer 
showed an important role in enhancing jatropha 
growth. Zinc is described as an essential component 
of thousands of proteins in plants; is acquired from 
the soil solution primarily as Zn2+, but also 
potentially complexed with organic ligands by roots, 
which feed the shoots via the xylem (BROADLEY 
et al., 2007). Copper is known to participate in 

numerous physiological processes and is an 
essential cofactor for many metalloprotein 
(YRUELA, 2005). 

Most of the commercial NPK products also 
contain a certain amount of Zn and Cu, such as Cu 
0.05% and Zn 0.05% in the product evaluated in this 
study. Although both elements are considered 
essential micronutrients for plant development, they 
can be toxic when in excess (YRUELA, 2005; 
BROADLEY et al., 2007; BADONI et al., 2016). 
Therefore, MDS-supplemented plants may have had 
experienced deleterious effects of high NPK doses 
as a function of excessive uptake of Zn and Cu. 

 
Leaf area, chlorophyll, and source-sink relations 

The higher LA values observed in response 
to NPK incorporation evidenced direct benefits on 



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Biosci. J., Uberlândia, v. 34, supplement 1, p. 17-27, Dec. 2018 

jatropha leaf production and expansion (Figure 2A). 
Similarly, recent studies in the literature have 
investigated NPK effects on jatropha, from early 
development through final yield, which have 
demonstrated effective response of this species to 
NPK fertilization (LIMA et al., 2016; NEGUSSIE et 
al., 2016). 

In contrast, chlorophyll content in MDS-
treated plants is not affected by NPK doses, 
showing high SPAD values even with no 
incorporation of NPK into the soil (Figure 2B). 
Therefore, the significant amount of Zn in MDS 
fertilizer formula (7.14%) may have contributed for 
the higher SPAD values, since this element is 
involved in the biosynthesis of chlorophyll, 
carotenoids and in scores of metabolic reactions 
(SUBBA et al., 2014). 

The similarities verified for LAR and LWR 
among plants treated or not treated with MDS 
fertilizer and indifference to NPK increment in the 
soil demonstrated the low response of these 
variables to both factors evaluated in this study 
(Figures 2C and 3A). When analyzing LAR for 
most regression models fitted to the data, a lower 
gap between treatments including the presence and 
absence of MDS was observed, i.e., a similar leaf 
area for the same production of plant dry weight. 
For LWR, a slightly difference in behavior was 
observed at 120 DAS in plants supplemented with 
NPK (7.4 g L-1) only, requiring a greater leaf area to 
produce the same amount of photoassimilates (lesser 
efficiency of the photosynthetic apparatus), and 
therefore resulting in less accumulation of 
photoassimilates in the plant (SHIPLEY, 2006; 
SOUZA et al., 2016). 

In this study, increasing NPK supply 
resulted in a slight increase in total leaf area for a 
given unit of plant biomass, i.e., LAR (Figure 2C). 
This resulted from increases in the area of light 
capture per biomass invested in leaves, i.e., SLA 
(FRESCHET et al., 2015), as we usually observed at 
80 DAS in jatropha plants growing without MDS 
(Figure 3B).  This may be related to low efficiency 
in the partition of photoassimilates in this group of 
plants compared to those that were treated with 
MDS, as the latter presented an enhanced source-
sink metabolism, and consequently, improved 
biomass allocation to the different plant organs 
(Figures 1and 2). 

It is also known that jatropha is an 
evergreen tree, which under natural conditions could 
be considered as an advantage trait, especially under 
abiotic stresses, such as low fertility or moisture in 
the soil. Thus, Poorter et al. (2015) believe that the 
SLA of evergreen woody species is about 2-3 times 

lower than that of deciduous species, and all else 
being equal, this lower SLA would have to be 
compensated by a 2-3 times higher leaf mass 
fraction to reach a similar LAI. Apparently, this LAI 
compensation was observed in plants supplemented 
with MDS and higher doses of NPK in detriment of 
SLA values, which showed effective response to 
both factors evaluated (Figure 3C). 

With LAI, a trend similar to the LA was 
observed regarding the regression model of the 
diverse treatments, with more evidence of 
improvement registered in MDS-treated plants. LAI 
is an important parameter in the growth analysis of a 
plant community, as it serves as an indicator of leaf 
ground cover (SHIPLEY, 2006; POORTER et al., 
2012). Furthermore, this variable was highly 
responsive to NPK doses when plants were also 
supplemented to MDS, showing a synergistic effect 
of both fertilizers at 80 DAS, although it 
disappeared by the end of this study (120 DAS). 
Therefore, changes in the availability of nutrients, 
represented here for either MDS or NPK sources, 
triggered phenotypic changes in functional traits that 
determine the ability of jatropha plants to acquire 
and thereby mitigate the constraints imposed by the 
limiting resource (FRESCHET et al., 2015). This 
highlights an interesting behavior of this species, as 
LAI is one of the most frequently used parameters 
for the analysis of canopy structure and is an 
important structural characteristic of crop 
monitoring and crop productivity (BEHERA et al., 
2010). 
 
Quantitative growth analysis estimates 

The similarities among the estimates in this 
quantitative analysis of jatropha growth represented 
by AGR, RGR and NAR variables, confirm the 
beneficial effects of MDS supplementation already 
discussed in this article (Figure 4). Hence, this 
treatment involving a fertilizer source of Zn (7.14%) 
drives this crop to faster growth and efficient 
biomass allocation throughout time, even without 
NPK incorporated into the soil. Zn is a necessary 
cofactor for many biological reactions, known to 
limit oxidative degradation of auxin and is 
necessary to maintain membrane integrity 
(TSONEV; LIDON, 2012). 

Although at 80 DAS this species was still 
positively responding to NPK increment, reversal 
behavior was seen in 120-day-old jatropha plants 
(Figure 4). These discrepancies certainly occur 
because AGR expresses the variation in plant 
growth (weight) for a given time, and the RGR is a 
measure of the speed with which a plant grows 



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Biosci. J., Uberlândia, v. 34, supplement 1, p. 17-27, Dec. 2018 

compared to its original size (EVANS, 1972; 
POORTER et al., 2012; BEADLE, 2014). 

Another important fact that must have 
affected the data observed in this study should be 
highlighted. Higher concentrations of Zn in the soil 
have direct effects on the growth and yield of plants 
(CHIBUIKE; OBIORA, 2014), and thus adversely 
affect agriculture (BADONI et al., 2016). Hussain 
and Maqsood (2010) emphasize that Zn 
concentration in soils lower than 125 ppm is 
considered optimum for the growth of plants. This 
certainly explains the drastic drop in NAR values of 
120 day-old plants treated with MDS and high doses 
of NPK, as they would be subjected to excessive Zn, 
including Zn already present in the soil, Zn provided 
by NPK incorporation, and Zn provided by frequent 
MDS applications (Figure 4C).  
 
CONCLUSIONS 

 
The effective response of jatropha young 

plants to MDS supplementation indicates that this 

fertilizer played a relevant role in this species 
metabolism, resulting in faster growth and enhanced 
biomass allocation. Consequently, MDS could be a 
potential candidate to replace NPK fertilizers during 
initial crop development, not only for its higher 
efficiency, but also because of economic and 
ecological reasons.  

Considering the reduction of NPK fertilizer 
and consequently potential reduction of nitrate 
runoff, the MDS fertilizer could be used as a 
standalone product or in conjunction with standard 
NPK fertilizers in lower doses.  
 
ACKNOWLEDGMENTS 

 
The authors thank the Coordination for the 

Improvement of Higher Education Personnel 
(Coordenação de Aperfeiçoamento de Pessoal de 
Nivel Superior – CAPES, Brazil) and the University 
of Florida for providing funding to support this 
project. 

 

 

RESUMO: Estudos abordando o desenvolvimento do pinhão manso (Jatropha curcas L.) através de análises de 
parâmetros quantitativos são limitados, especialmente em relação à resposta a diferentes tipos e doses de fertilizantes. Para 
investigar os efeitos de um sistema de fornecimento de micronutrientes (MDS), realizou-se uma análise quantitativa 
completa do crescimento de plantas jovens de pinhão manso comparando a eficácia deste sistema sob diferentes doses de 
NPK. As plantas foram cultivadas por 120 dias em potes de 3,9 L contendo solo local, com ou sem MDS (parcela 
principal), combinado com doses de NPK (0; 1,8; 4,7 e 7,4 g L-1) nas subparcelas. Curvas dose-resposta das análises 
quantitativas das variáveis foram geradas para três períodos (40, 80 e 120 dias após semeadura), como uma sub-
subparcela. As análises quantitativas de crescimento mostraram que a maioria dos parâmetros avaliados neste estudo foi 
melhorada pela aplicação do MDS, resultando em benefícios para o crescimento inicial do pinhão-manso, independemente 
da dose de NPK. Mesmo sem suplementação de NPK ou sob a dose mais baixa avaliada (1,8 g L-1), o MDS proporcionou 
melhor crescimento do pinhão manso, sendo geralmente equivalente às maiores doses de NPK (4,7 e 7,4 g L-1) sem MDS. 
A resposta efetiva das plantas jovens do pinhão manso à suplementação com MDS indica que este tipo de fertilizante 
desempenhou um papel relevante no metabolismo desta espécie, resultando em um crescimento mais rápido e melhor 
alocação de biomassa. 

 
PALAVRAS-CHAVE: Nutrientes minerais biodisponíveis; Fertilizante com micronutrientes; Jatropha curcas 

L.; Alocação de biomassa; Ecofisiologia. 
 
 

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