Final SPH -JHS Coverpage 16-2 Jan 2021 single




C O N T E N T S

JOURNAL OF HORTICULTURAL SCIENCES

Volume 16 Issue 2 June 2021

In this Issue i-ii

Review
Phytoremediation of indoor air pollutants: Harnessing the potential of 131-143
plants beyond aesthetics
Shalini Jhanji and U.K.Dhatt

Research Articles
Response of fruit yield and quality to foliar application of micro-nutrients in 144-151
lemon [Citrus limon (L.) Burm.] cv. Assam lemon
Sheikh K.H.A., Singh B., Haokip S.W., Shankar K., Debbarma R.
Studies on high density planting and nutrient requirement of banana in 152-163
different states of India
Debnath Sanjit Bauri F.K., Swain S., Patel A.N., Patel A.R., Shaikh N.B.,
Bhalerao V.P., Baruah K., Manju P.R., Suma A., Menon R., Gutam S. and P. Patil
Mineral nutrient composition in leaf and root tissues of fifteen polyembryonic 164-176
mango genotypes grown under varying levels of salinity
Nimbolkar P.K., Kurian R.M., Varalakshmi L.R., Upreti K.K., Laxman R.H. and
D. Kalaivanan
Optimization of GA3 concentration for improved bunch and berry quality in 177-184
grape cv. Crimson Seedless (Vitis vinifera L)
Satisha J., Kumar Sampath P. and Upreti K.K.
RGAP molecular marker for resistance against yellow mosaic disease in 185-192
ridge gourd [Luffa acutangula (L.) Roxb.]
Kaur M., Varalakshmi B., Kumar M., Lakshmana Reddy D.C.,
Mahesha B. and Pitchaimuthu M.
Genetic divergence study in bitter gourd (Momordica charantia L.) 193-198
Nithinkumar K.R., Kumar J.S.A., Varalakshmi B, Mushrif S.K.,
Ramachandra R.K. , Prashanth S.J.
Combining ability studies to develop superior hybrids in bell pepper 199-205
(Capsicum annuum var. grossum L.)
Varsha V., Smaranika Mishra, Lingaiah H.B., Venugopalan R., Rao K.V.
Kattegoudar J. and Madhavi Reddy K.
SSR marker development in Abelmoschus esculentus (L.) Moench 206-214
using transcriptome sequencing and genetic diversity studies
Gayathri M., Pitchaimuthu M. and K.V. Ravishankar



Generation mean analysis of important yield traits in Bitter gourd 215-221
(Momordica charantia)
Swamini Bhoi, Varalakshmi B., Rao E.S., Pitchaimuthu M. and Hima Bindu K.

Influence of phenophase based irrigation and fertigation schedule on vegetative 222-233
performance of chrysanthemum (Dendranthema grandiflora Tzelev.) var. Marigold
Vijayakumar S., Sujatha A. Nair, Nair A.K., Laxman R.H. and Kalaivanan D.

Performance evaluation of double type tuberose IIHR-4 (IC-0633777) for 234-240
flower yield, quality and biotic stress response
Bharathi T.U., Meenakshi Srinivas, Umamaheswari R. and Sonavane, P.

Anti-fungal activity of Trichoderma atroviride against Fusarium oxysporum f. sp. 241-250
Lycopersici causing wilt disease of tomato
Yogalakshmi S., Thiruvudainambi S., Kalpana K., Thamizh Vendan R. and Oviya R.

Seed transmission of bean common mosaic virus-blackeye cowpea mosaic strain 251-260
(BCMV-BlCM) threaten cowpea seed health in the Ashanti and
Brong-Ahafo regions of Ghana
Adams F.K., Kumar P.L., Kwoseh C., Ogunsanya P., Akromah R. and Tetteh R.

Effect of container size and types on the root phenotypic characters of Capsicum 261-270
Raviteja M.S.V., Laxman R.H., Rashmi K., Kannan S., Namratha M.R. and
Madhavi Reddy K.

Physio-morphological and mechanical properties of chillies for 271-279
mechanical harvesting
Yella Swami C., Senthil Kumaran G., Naik R.K., Reddy B.S. and Rathina Kumari A.C.

Assessment of soil and water quality status of rose growing areas of 280-286
Rajasthan and Uttar Pradesh in India
Varalakshmi LR., Tejaswini P., Rajendiran S. and K.K. Upreti

Qualitative and organoleptic evaluation of immature cashew kernels under storage 287-291
Sharon Jacob and Sobhana A.

Physical quality of coffee bean (Coffea arabica L.) as affected by harvesting and 292-300
drying methods
Chala T., Lamessa K. and Jalata Z

Vegetative vigour, yield and field tolerance to leaf rust in four F1 hybrids of 301-308
coffee (Coffea arabica L.) in India
Divya K. Das, Shivanna M.B. and Prakash N.S.

Limonene extraction from the zest of Citrus sinensis, Citrus limon, Vitis vinifera 309-314
and evaluation of its antimicrobial activity
Wani A.K., Singh R., Mir T.G. and Akhtar N.

Event Report 315-318
National Horticultural Fair 2021 - A Success Story
Dhananjaya M.V., Upreti K.K. and Dinesh M.R.

Subject index 319-321

Author index 322-323



J. Hortl. Sci.
Vol. 16(2) : 144-151, 2021

This is an open access article d istributed under the terms of Creative Commons Attribution-NonCommer cial-ShareAl ike 4.0 International License,
which permits unrestricted non-commercial use, d istribution, and reproduction in any med ium, provide d the original author and source are credited.

Original Research Paper

Response of fruit yield and quality to foliar application of micro-nutrients in
lemon [Citrus limon (L.) Burm.] cv. Assam lemon

Sheikh, K.H.A.1*,  Singh, B.1, Haokip, S.W.1, Shankar, K.1, Debbarma, R.1,
Gaitri Devi, A.2 and Nengparmoi T.H.3

1Department of Fruit Science, 2Department of Vegetable Science,
College of Horticulture and Forestry,  Central Agricultural University,

Pasighat-791102, Arunachal Pradesh, India
3Department of Agronomy, College of Agriculture, Vellanikkara, Kerala Agricultural University, Thrissur, Kerala - 680656

*Corresponding Author Email : sheikh4261@gmail.com

ABSTRACT
Assam lemon [Citrus limon (L.) Burm.], an indigenous lemon cultivar of Assam, is widely
cultivated in warm southern slopes of the Himalayas in North-Eastern India. Since this cultivar
of lemon is having a prominent trait of bearing fruits in several flushes throughout the year, it
is essential to provide sufficient nutrition for obtaining optimum yield with good quality fruits.
In the current experiment, a randomized block design having twelve treatments with three
replications was followed to find out the response of lemon fruit yield and quality to foliar
application of micronutrients during the year 2019. Among all, the treatment ZnSO4 (0.2%) +
FeSO4 (0.2%) + Borax (0.2%) + CuSO4 (0.2%) gave the best performance in improving the
yield and quality of fruits. The highest number of fruits per plant at the time of harvesting (73),
yield per plant (11.5 kg), fruit fresh weight (158 g), fruit length (9.60 cm), fruit diameter (5.80
cm), juice content (152 mL/fruit), TSS (6.40 °B), ascorbic acid (49.10 mg/100g), total sugar
(6.30%), reducing sugar (3.90%), non-reducing sugar (2.40%) with lowest titratable acidity
(3.13%) were obtained which revealed that the yield and fruit quality of lemon depends on the
application of different micronutrients.

Keywords: Assam lemon, fruit quality, micronutrients, nutrition and yield

INTRODUCTION

Citrus is considered as one of the most important fruits
widely cultivated in different parts of the world. It
belongs to the family Rutaceae. It is very famous for
its juice and pulp all over the world. Among the citrus
cultivar, Assam lemon [Citrus limon (L.) Burm.] is
an indigenous lemon cultivar of Assam and is grown
all over the North-Eastern region. As this plant is
having a prominent trait of bearing fruits in several
flushes throughout the year, it is essential to provide
sufficient nutrition for obtaining optimum yield with
good quality fruits. Micronutrients like zinc, iron,
boron and copper are not only essential but they are
equally significant like other macronutrients, in spite
of their requirement in minute quantities. They also
play a vital role in the various enzymatic activities and
synthesis. Their acute deficiencies are sometimes
incurable in nature (Kumar, 2002). Zinc is required

for the synthesis of tryptophan which is the precursor
of indole acetic acid synthesis resulting in the growth
and development of tissues. Iron is also an important
micronutrient necessary for the citrus plants. It has
been reported that the application of iron sulphates as
folia r  spr a y r educes the lea f chlor osis a nd
consequently increase the yield (Devi et al., 1997). It
also helps in a significant increase of fruit yield, fruit
volume, ascorbic acid content and leaf iron content in
citrus (Aboutalebi and Hassanzadeh, 2013). Similarly,
boron also plays a vital role in the growth behaviour
and productivity of citrus fruits. It increases the
phenolic compound production in the plant system that
is responsible for the polar transport of auxin. This
increases the auxin activity resulting in increasing the
vegetative growth of citrus trees (Gurjar et al., 2015).
Boron also helps in pollen grain germination and



145

Response of fruit yield and quality to foliar application of micro-nutrients in lemon

J. Hortl. Sci.
Vol. 16(2) : 144-151, 2021

elongation of pollen tubes that results in increasing the
fruit set percentage and ultimately increase in yield
(Abd-Allah, 2006).  As a micronutrient, copper plays
a significant role in plants. It is involved in stimulation
activities for lignification of the cell wall of plants,
and photosynthesis, and acts as an electron carrier in
the plant system (Somasundaram et al., 2011). It is
reported that copper helps in production of sugar
compounds and leads to more accumulation of total
soluble solids (TSS) in the fruit juice (Singh et al.,
2018).

Since citrus is a micronutrient loving crop, the more
precise management of nutrition is required to meet
the nutrient demand for its growth and development.
Thus, fulfilling the nutritional requirement is very
important for economically profitable citrus fruit
production. Assam lemon being a heavy and regular
bearing crop which bears throughout the year has to
be supplied with adequate nutrients to ensure the yield
and quality of the harvest. Most of the time citrus
growers are not giving proper emphasis to application
of micronutrients, as they are required in minute
quantities. This leads to a drastic decrease in the
growth and development of plants and it also affects
the yield a nd quality of fruits. So, the curr ent
experiment was conducted to study the effect of
micronutrients on fruit yield and quality of Assam
lemon in the North-Eastern region of India.

MATERIAL AND METHODS
The experiment was laid out with the objectives of
eva lua ting a nd sta nda r dizing the impa ct of
micronutrients on yield and quality of Assam lemon.
The research work was executed on three years old
Assam lemon plants which were planted at the spacing
of 3m x 3m during the year 2019 at the Citrus Fruit
Block, Department of Fruit Science of the College of
Horticulture and Forestry, Central Agricultural
University, Pa sigha t,  Aruna cha l Pr adesh. It is
geographically located at 28° 04’ 43" N latitude and
95° 19’ 26" E longitude with an altitude of 153 m
above the mean sea level. Pasighat lies under the
humid sub-tropical climate. The average annual
rainfall and temperature of this area are 32.8 cm and
25.5 ºC, respectively. The rainy season starts from
June and it continues till September with maximum
rainfall during July. August is the warmest month of
the year while December is the coldest month of the
year with the average temperature of 31.60C and

20.50C P C respectively. The design of the experiment
followed was Randomized Block Design (RBD)
having twelve treatments and each treatment was
replicated thrice. In each replication, there were two
plants and the total numbers of plants in the whole
experiment were seventy-two. The recommended dose
of fertilizer (RDF) for Assam lemon 100: 100: 100 g
NPK (Source: N- Urea, P- SSP and K- MOP)/plant/
year (www.kiran.nic.in), was applied to all the plants
under the investigation. Half of the dose before
flowering during the first week of January and the
remaining half dose during the second month of June
were applied.

The treatments studied were: T1 - Control, T2 - ZnSO4
(0.2%), T3 - FeSO4 (0.2%), T4 - Borax (0.2%), T5 -
CuSO4 (0.2%), T6 - ZnSO4 (0.2%) + FeSO4 (0.2%),
T7 - ZnSO4 (0.2%) + Borax (0.2%), T8 - ZnSO4
(0.2%) + CuSO4 (0.2%), T9 - FeSO4 (0.2%) + Borax
(0.2%), T10 - FeSO4 (0.2%) + CuSO4 (0.2%), T11 -
Borax (0.2%) + CuSO4 (0.2%) and T12 - ZnSO4 (0.2%)
+ FeSO4 (0.2%) + Borax (0.2%) + CuSO4 (0.2%). For
the foliar application of these micronutrients (Sources:
ZnSO4- 36.40% Zn, FeSO4- 32.8% Fe, Borax- 10.8%
B and CuSO4- 21% Cu), the required amounts of
micronutrient sources were dissolved in separate
container. Then the pH of the nutrient solutions were
checked by using Pen type digital pH meter and it was
adjusted by 0.1 N concentrated hydrochloric acid and
sodium hydroxide. The application was done on 5th
April, 2019 (i.e.) after the complete emergence of
spring flush and the onset of fruit setting) on an
average of two liters per tree and normal water was
used for spraying the plants in control by using
Knapsack sprayer. In each spray treatment teepol @
0.01% was added as sticking gent in prepared solution.

The total numbers of fruits per plant at the time of
harvesting (i.e.) during June-July fruits developed
attractive green to little yellow colour and they were
harvested two times) were recorded. For fruit yield of
Assam lemon, fruits from each plant were harvested
separately for all treatments and yield per plant was
calculated by multiplying total number of fruits per
plant with average fruit weight. For recording the
readings of physical parameters like fruit weight, fruit
length, fruit diameter and juice content, five fruits from
each treatment were selected randomly. Then the fruit
weight was recorded by using a precision weighing
balance and its average weight was expressed in grams



146

Sheikh et al

(g). For the fruit length and fruit diameter a digital
Vernier caliper was used to record the data and their
average fruit length and fruit diameter were expressed
in centimeters (cm). Fruit juice content was also
measured by using a measuring cylinder and its
average juice content per fruit was expressed in
milliliters (mL).
The TSS in fruit juice was determined using hand held
Refractometer (0 ºB–32 ºB). The titratable acidity of
the fruit was determined by titrating the fruit juice
against 0.1N NaOH solution using phenolphthalein as
an indicator (light pink end point) and expressed as
percentage in terms of citric acid (AOAC, 2002).
Total sugar content was estimated by anthrone method
as described by Hodge and Hofreiter (1962).
Reducing suga r  content wa s estima ted by
spectrophotometric method as described by Somogyi
(1952). The non-reducing sugar content was obtained
by the subtraction of the reducing sugar content from
the total sugar content.
Non reducing sugars content = total sugar - reducing
sugar
The ascorbic acid content of fruits was determined by
the method described by Ranganna (1986) using 2, 6-
dichlorophenol Indophenol dye. The samples extracted
in meta-phosphoric acid solution were titrated with dye
to pink end point. The ascorbic acid content was
calculated and expressed as mg per 100 g of fruit
weight sample.
The observations recorded during field experiment
and data obtained from laboratory analysis were
subjected to the statistical analysis of variance for
RBD. Significance and non-significance of the
va r ia nc e du e t o diff er ent  t r ea t ment s  wer e
determined by calculating the respective ‘F’ values
according to the method described by Gomez and
Gomez (2010).

RESULTS AND DISCUSSION
Yield and its attributing parameters: The data
depicted in Table 1 exhibited the significant impact
of foliar imposition of micronutrients on yield and
its attributing parameters. The highest number of
fruits per plant (73) at the time of harvesting and
fruit yield (11.52 kg/plant) was recorded in T 1 2
[ZnSO4 (0.2%) + FeSO4 (0.2%) + Borax (0.2%) +
CuSO4 (0.2%)] while the lowest number of fruits
per plant (43) at the time of harvesting and fruit
yield (5.60 kg/plant) was obtained in T1 (Control).

This might be due to the synergistic effect of different
micronutrients as they directly take part in many
physiological processes and activity of many enzymes
for greater gathering of food materials. Zinc helps in
prevention of abscission layer formation and increase
the synthesis of tryptophan which is the precursor of
auxin synthesis and this facilitates the ovary to remain
intact with the shoot, ensuring in minimizing the flower
and fruit drop and maximize the retention of fruits in
the plants (Gurjar et al., 2015). There is also a
correlation between fruit drop and internal hormonal
level in the plant system. As the level of internal auxin
concentration in the plant system is higher, then the
fruit retention capacity will be more leading to increase
in number of fruits per plant. Iron also plays a major
role in cell division and cell enlargement resulting in
increasing the fruit size and fruit weight which
ultimately leads to the increase in yield of plants.
Ganie et al. (2013) reported that boron helps in
germination of pollen grains and elongation of pollen
tube because of which the fruit set, fruit retention and
yield of the guava plants were increased. Copper
involves in synthesis and stability of chlorophyll
responsible to produce food materials required for the
growth and development of fruits. Ilyas et al. (2015)
observed the significant improvement of photosynthetic
and fruit yield in Citrus reticulata Blanco var. Kinnow
on the foliar imposition of Zn, Cu and B. Similarly,
Zoremtluangi et al., (2019) also proved that the foliar
application of Zn, Cu and B obtained the maximum
number of fruits per plant and yield per tree. The
present report is in conformity with the experimental
findings revealed by Bhoyar and Ramdevputra (2016)
in guava and Jangid et al. (2019) in aonla.

Physical parameters of fruits: Most of the physical
parameters of the Assam lemon fruit had consequential
effect due to the application of different micronutrients
and they are presented in Table 1. The highest fruit
fresh weight (157.77 g), juice content (152 mL/fruit),
fruit length (9.60 cm) and fruit diameter (5.80 cm)
were obtained in treatment T12[ZnSO4 (0.2%) + FeSO4
(0.2%) + Borax (0.2%) + CuSO4 (0.2%)] while the
lowest fruit fresh weight (130.20 g), juice content (120
mL/fruit), fruit length (7.43 cm) and fruit diameter
(4.10 cm) were obtained in treatment T1 (Control).

The overall amelioration in the physical parameters
of the Assa m lemon fruit might be because of
benefaction of different micronutrients in the growth
and development of fruits. Zinc facilitates in the

J. Hortl. Sci.
Vol. 16(2) : 144-151, 2021



147

Table 1. Effect of micronutrients on yield and physical parameters of Assam lemon

Treatments Number of Fruit Fruit Fruit Fruit Juice
fruits/plant yield Fresh length diameter content

(kg/plant) weight (g) (cm) (cm) (mL/fruit)

T1 43 5.60 130.2 7.43 4.10 120

T2 58 8.40 144.60 8.57 5.00 135

T3 48 6.64 138.40 7.87 4.67 129

T4 54 7.68 142.10 8.33 4.90 134

T5 45 6.00 133.30 7.60 4.27 123

T6 70 10.84 155.00 9.43 5.73 149

T7 67 10.11 150.80 9.27 5.50 145

T8 63 9.34 148.13 8.90 5.33 141

T9 52 7.29 140.23 8.13 4.73 131

T10 47 6.38 135.70 7.77 4.43 127

T11 61 8.95 146.60 8.73 5.13 137

T12 73 11.52 157.77 9.60 5.80 152

C.D. (0.05) 7.22 1.17 5.02 0.85 0.54 4.01

SEm± 2.44 0.39 1.70 0.28 0.18 1.36

synthesis of tryptophan, the precursor of auxin
synthesis and consequently the auxin level in the fruit
increases. This lead to the higher enlargement of cell
because of cell vacuolization resulting in increased size
of vesicles, dimension of locules and eventually the
weight and size of fruit. Therefore, the significant
influence of Zn in increasing the fruit fresh weight was
revealed by Ghosh and Besra (2000) in sweet orange.
Iron and zinc also play a vital role in the enlargement
of cell, division of cell and formation of starch. Thus,
the additive effect of these micronutrients resulted in
increased fruit fresh weight. The rise in fruit fresh
weight might be because of the higher translocation
of photosynthates to fruits. Similar findings were
revealed by Waskela et al. (2013) in guava.

Boron also plays a vital role in cell division and cell
elongation, thereby increasing the fresh weight of fruit.
The increase in fruit fresh weight owing to the
combined imposition of Zn and B may be the result
of stimulation influence on plant metabolic process.

In addition to this, B also activates the sugar and water
mobilization in the fruits resulted in increasing the fruit
weight as reported by Lakshmipathi et al. (2015).
Similarly, Ilyas et al. (2015) also reported that the
foliar imposition of Zn, Cu and B had significant effect
on fruit yield with regard to number and fresh weight
of fruit.

Trivedi et al. (2012) reported that zinc controls the
semi-permeability of cell wall through which the
movement of water into fruits increases, that results
in obtaining the highest juice content in guava. Sajid
et al. (2012) also revealed that the foliar spray of Zn
and B had consequential influence on juice content in
fr uits of sweet or a nge.  T he imposition of
micronutrients might have ameliorated the plant health
by improving the sugar metabolism and conduction of
assimilates as a result of which the fruit juice content
increase. Similar outcomes were revealed by the
findings of Singh et al. (2018) in sweet orange cv.
Mosambi. Increase in fruit length might be because

Response of fruit yield and quality to foliar application of micro-nutrients in lemon

J. Hortl. Sci.
Vol. 16(2) : 144-151, 2021



148

of the direct effect of B and Zn in increasing the cell
division and cell elongation process. Similarly, the fruit
diameter was notably influenced by the imposition of
zinc sulphate and borax. Dutta and Banik (2005)
reported that the increase in fruit length and fruit
diameter may be due to the improvement in internal
physiology of developing fruit with regard to proper
supply of wa ter,  miner a l nutr ients a nd other
compounds essentia l for  nor ma l gr owth a nd
development of fruit and the present result is in
conformity with the reports of Yadav et al. (2013).

Quality parameters of fruit: The quality parameters
of fruits were significantly improved by the foliar
application of micronutrients and they are presented
in Table 2. In this, the treatment T12[ZnSO4 (0.2%) +
FeSO4 (0.2%) + Borax (0.2%) + CuSO4 (0.2%)]
offered maximum TSS (6.40 ºB), ascorbic acid (49.10
mg/100 g), total sugars (6.30%), reducing sugars
(3.90%) and non-reducing sugars (2.40%) content of
fruits while the minimum TSS (5.30 ºB), ascorbic acid
(34.37 mg/100 g), total sugars (3.73%), reducing
sugars (2.53%) and non-reducing sugars (1.20%) were
obtained in T1 (Control).

Table 2. Effect of micronutrients on quality parameters of Assam lemon

Treatments TSS Ascorbic Titratable Total Reducing Non reducing
(°Brix) acid acidity sugar sugar sugar

(mg/100g) (%) (%) (%) (%)

T1 5.30 34.37 4.93 3.73 2.53 1.20

T2 5.93 40.43 4.57 4.80 2.90 1.90

T3 5.50 35.27 4.63 5.13 3.17 1.97

T4 5.60 39.55 4.47 4.37 2.70 1.67

T5 5.83 37.09 4.33 4.63 2.83 1.80

T6 6.13 42.33 3.90 6.00 3.80 1.20

T7 6.00 46.83 3.73 5.53 3.43 2.10

T8 6.20 48.30 3.57 5.73 3.70 2.03

T9 5.90 45.13 3.47 5.67 3.57 2.10

T10 5.97 41.06 3.23 5.37 3.13 2.23

T11 5.80 47.70 3.67 5.47 3.27 2.20

T12 6.40 49.10 3.13 6.30 3.90 2.40

C.D. (0.05) 0.44 3.31 0.39 0.27 0.24 0.40

SEm± 0.15 1.12 0.13 0.09 0.08 0.13

Zinc is required in enzymatic reactions namely
hexokinase, carbohydrate and protein synthesis. In
addition to this, Boron helps in the transportation of
sugar in the form of boron-sugar complex and it also
intensifies hydrolysis of carbohydrates into simple
suga r.  Copper  a lso helps in eleva ting the
photosynthetic efficiency that results in higher rate of
photosynthesis. The main product of photosynthesis

is sugar, thus increase in the photosynthesis by the
additive action of zinc, boron and copper results in
mor e suga r  compounds a nd this led to the
accumulation of more total soluble solids in fruit juice.
The results of the current investigation are in line with
the results obtained by Babu and Yadav (2005) in
Khasi mandarin and Singh et al. (2018) in Sweet
orange cv. Mosambi. Kumari et al. (2009) also

Sheikh et al

J. Hortl. Sci.
Vol. 16(2) : 144-151, 2021



149

reported that the foliar fertilization of Fe, Zn and Cu
had significant effect in increasing the TSS of Kinnow
mandarin.

Zinc helps in the synthesis of auxin that leads to the
increase in ascorbic acid content as reported by Nawaz
et al. (2008). Similarly, foliar imposition of Zn, B and
Cu also helps in increasing the ascorbic acid content
in the fruit juice of Sweet orange cv. Mosambi as
reported by Singh et al. (2018). Increase in sugar
content (total sugar, reducing sugar and non-reducing
sugar) in the fruit juice of Assam lemon might be
because of the active participation of Zn, Cu and B
in photosynthesis and faster translocation of sugars
from the site of synthesis to the developing fruits. The
other reason might be due to the decrease in starch
content during deterioration of acid and quick transfer
of sugars in the fruit. Thus, the present findings are
in line with the outcomes obtained by El-Rahman
(2003) in Naval Orange and Bhatt et al. (2012) in
mango.

Although, the lowest value of titratable acidity
(3.13%) of fruit juice was observed in T12[ZnSO4
(0.2%) + FeSO4 (0.2%) + Borax (0.2%) + CuSO4
(0.2%)] while the highest titratable acidity (4.93%)
was recor ded in T 1 (Control). The reduction of
titratable acidity might be because of more synthesis

of nucleic acids due to more availability of plant
metabolites as reported by Ullah et al. (2012) in
Kinnow mandarin. The other reason might be because
of their  utiliza tion in r espir a tion a nd quick
transformation of organic acid into sugars as disclosed
by Brahmachari et al. (1997) in litchi. Similarly, the
outcomes are in agreement with the results obtained
by Sau et al. (2018) in guava.

On the basis of the experimental evidence obtained
from the current research work, it is concluded that
the imposition of recommended dose of N, P and K
fertilizers (100g: 100g: 100g NPK/plant/year) together
with foliar spray of ZnSO4 (0.2%) + FeSO4 (0.2%) +
Borax (0.2%) + CuSO4 (0.2%) once (two weeks after
fruit setting) can be advocated to Assam lemon
growers as the most potent measures to enhance the
number of fruits per plant, yield per plant  and fruit
quality that will eventually increase the productivity.

ACKNOWLEDGEMENT
The authors would like to express the heartfelt and
sincere thanks to the Department of Fruit Science,
College of Hor ticulture a nd For estr y, Centr a l
Agricultural University, Pasighat, Arunachal Pradesh,
for the guidance and needful help during the entire
course of the experiment.

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(Received on 14.04.2021, Revised on 13.09.2021 and Accepted on 26.10.2021)

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Vol. 16(2) : 144-151, 2021


	00 Contents.pdf
	02 Sheikh.pdf
	19 Lamesssa.pdf
	20 Divya.pdf
	21 Wani.pdf
	23 Index  and Last Pages.pdf