INTRODUCTION

Cape gooseberry (Physalis peruviana L.), commonly
known as Rasbhari, is a quick- growing herbaceous crop
belonging to the family Solanaceae. The fruit resembles
tomato in shape but is smaller in size. It is ideal as a jam-
fruit owing to its rich pectin content. Apart from being rich
in food value, plants of Cape gooseberry are high yielding
and the crop is highly remunerative due to low production
costs and a short juvenile period. This potential cash crop
can also be grown as an intercrop. However, ultimately, its
growth and yield depends upon orchard management
practices, with Nutrient management being one of the prime
considerations for higher yield.

Inorganic fertilizers are commonly used by most
farmers because of relatively quick availability of nutrients
to the plant, but their continuous use leads to damage to the
ecosystem and soil health. Moreover, indiscriminate use of
high amounts of chemical fertilizers results in deficiency of
nutrients other than those applied. Thus, there is need to lay
emphasis on management of natural resources like
biofertilizers, etc. Biofertilizers are not a substitute but a
supplement to chemical fertilizers for maximizing yield and
also, to maintain a balance in the agro-ecosystem. There
are reports of usefulness of these biofertilizers in other crops

Effect of integrated nutrient management strategies on growth and yield of Cape
gooseberry (Physalis peruviana L.)

Savreet Sandhu and Bikramjit Singh Gill
Department of Horticulture, Faculty of Agriculture

Khalsa College, Amritsar -143002, India
 E-mail: savreetz@gmail.com

ABSTRACT

An investigation was undertaken during 2009-10 to study the impact of integrated nutrient management on growth
and yield of Cape gooseberry genotype ‘Aligarh’. Treatments consisted of application of biofertilizers (Azotobacter,
Azospirillium and Pseudomonas) applied alone or in combination, with 75% and 100% NPK, plus full dose of FYM.
The experiment was laid out in Randomized Block Design with twenty treatments replicated thrice. Seedlings inoculated
with Azotobacter + 100% NPK + FYM gave maximum plant height, stem thickness, shoot number per plant and fruit
yield per plant. Treatment of Azotobacter inoculation + 75% NPK +FYM gave maximum leaf area and minimum days
to fruit picking. Biological routes to improving soil fertility and soil health for optimum crop production, therefore,
form a vital component of integrated nutrient management.

Key words: Cape gooseberry, Aligarh, biofertilizers, NPK, FYM, growth, yield

of Solanaceae family, such as tomato, but none in Cape
gooseberry. With this in view, the present experiment was
undertaken to work out an optimum combination of biological
and chemical sources of nutrients in Cape gooseberry.

MATERIAL AND METHODS

The investigation on integrated nutrient management
in Cape gooseberry was carried out at an experimental
orchard and laboratory of Department of Horticulture,
Khalsa College, Amritsar during 2009-10. For raising a
nursery, seeds of Cape gooseberry genotype ‘Aligarh’ were
sown on 15 June 2009 in raised nursery beds measuring 1m
x 1m. Seedlings were transplanted a month after sowing
i.e., in mid July (when these attained a height of 20cm) in
well-prepared field beds measuring 2m x 3m. Plant-to-plant
and row-to-row spacing was 1m x 1m. A unit of 6 plants/
plot comprised a single treatment. The experiment was laid
out in Randomized Block Design. Twenty treatment
combinations were replicated thrice.

Non-symbiotic biofertilizers (Azotobacter,
Azospirillium and Pseudomonas), well known for their
broad spectrum utility in various crops, were used in the
experiment. These were applied as seedling treatment @
1.5kg/ha and mixed proportionately in combined applications.
Standard dose of NPK (10, 10 and 5g/plant) and FYM

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30

(1kg/plant) was used as the control. Source of fertilizer
applied was calcium ammonium nitrate (N 25%) for nitrogen,
single super phosphate (P 16%) for phosphorus, and, muriate
of potash (K 60%) for potassium. All of the phosphorus
and potassium was applied during final preparation of the
soil before making the beds, while, half of the nitrogen was
applied 30 days after transplanting and the rest was applied
after 25 days. Effect of different combinations of chemical
and biological fertilizers on crop growth was recorded in
terms of plant height, plant spread (N-S and E-W), stem
thickness, shoot number per plant and leaf area, as per
standard procedures. Apart from this, days to fruit picking
from transplanting, and fruit-yield per plant, were also
recorded. Total fruit yield was recorded on the basis of four
pickings.

Treatment details
T

1
- Azotobacter

T
2

- Azospirillium
T

3
- Pseudomonas

T
4

- Azotobacter + Azospirillium
T

5
- Azotobacter + Pseudomonas

T
6

- Azospirillium + Pseudomonas
T

7
- Azotobacter + Azospirillium + Pseudomonas

T
8

- Azotobacter + 100% NPK
T

9
- Azotobacter + 75% NPK

T
10

- Azospirillium + 100% NPK
T

11
- Azospirillium + 75% NPK

T
12

- Pseudomonas + 100% NPK
T

13
- Pseudomonas + 75% NPK

T
14

- Azotobacter + 100% NPK +FYM
T

15
- Azotobacter + 75% NPK + FYM

T
16

- Azospirillium + 100% NPK + FYM
T

17
- Azospirillium + 75% NPK + FYM

T
18

- Pseudomonas + 100% NPK + FYM
T

19
- Pseudomonas + 75% NPK + FYM

T
20

- Control (Recommended dose of NPK and FYM)

RESULTS AND DISCUSSION

Plant height and plant spread (N-S and E-W)
increased significantly by biofertilization application
compared to the control (Table 1). Maximum height was
recorded in Azotobacter inoculation of seedlings + 100%
NPK + FYM (T

14
). Increase in height may be due to the

fact that nitrogen is fixed by Azotobacter and, N being a
constituent of protein and chlorophyll, plays a vital role in
photosynthesis. It enhances accumulation of carbohydrates
which, in turn, increase growth of plants (Mahmoud and
Amara, 2000). The reason for increased plant height and

plant spread may be the build up of colonies of the applied
biofertilizer inoculates and their growth promoting effects,
including synthesis of plant growth promoting substances.
This increase in vegetative growth may also be attributed
to enhanced availability of nutrients at vital periods of
growth, greater synthesis of carbohydrates and translocation,
improved water status of plants, and, increased nitrate
reductase activity. Plant spread improved significantly with
inoculation of biofertilizers due to increased cell metabolism
resulting from enchanced enzyme activity, chlorophyll
content and photosynthetic processes (Kumar et al, 2006).

Stem thickness was also found to increase significantly
with application of biofertilizers compared to the control
(Table 1). Maximum value was recorded in Azotobacter
inoculation of seedlings + 100% NPK + FYM (T

14
), followed

by Azotobacter inoculation of seedlings + 75% NPK +
FYM (T

15
). Increase in stem thickness can be attributed to

stimulative activity of the microflora in rhizosphere, leading
to increased nutrient availability and, thereby, vigorous plant
growth.

Singh and Singh (2004) reported that Azotobacter
inoculation increased N levels in soil. This increase in N
status might be partly attributed to stimulative effect of plant
bioregulators which, in turn, increased the rate of nutrient
absorption and translocation within the plant system
consequently, more N accumulated in the plant parts
(Awasthi et al, 1998) resulting in overall tree growth. When
all three nutrient sources, viz. FYM, inorganic fertilizer and
biofertilizer (Azotobacter) were applied, it resulted in better
plant growth. This can be attributed to improved nutrient
and water availability, leading to plant growth from
development of better root system with concomitant increase
in number of rootlets. This is corroborated by findings of
Prahraj et al (2002). Increased plant growth might be due
to more efficient absorption of nutrient elements because
of the better root system developed by biofertilization.
Increase in plant-growth can also be ascribed to N addition
through biological nitrogen fixation by Azotobacter
(Bhattacharya et al, 2002).

Azotobacter inoculation of seedlings + 75% NPK +
FYM (T

15
) showed minimum number of days to first picking

of fruits from date of transplanting seedlings compared to
the control (Table 1). This may be due to the ellaboration of
small quantities of growth promoting substances like GA,
IAA, cytokinins, Vitamin B, etc., by Azotobacter, which,
along with NPK and FYM might have improved the
physiology of plants causing a shift from the vegetative to
the reproductive phase (Nair and Najachandra, 1995).

Sandhu and Gill

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Vol. 6(1):29-32, 2011



31

Maximum leaf area was observed in the treatment
Azotobacter inoculation of seedlings + 75% NPK + FYM.
It can be inferred that biofertilization, along with NPK and
FYM, helps proliferation of roots which, ultimately, results
in sturdy and healthy plants showing resistance to biotic
and abiotic stresses. Moreover, this also promotes better
nutrient uptake and carbohydrate accumulation in leaves,
resulting in healthy leaf growth.

Maximum shoot number per plant and fruit yield per
plant was obtained in Azotobacter inoculation to seedlings
+ 100% NPK + FYM (T

14
). The reason for increased

number of shoots and fruits per plant is due to solubilization
effect of plant nutrients by addition of FYM, as evidenced
by increased uptake of N, P, K, Ca and Mg by the crop
during the vegetative as well as reproductive phase. These
results are in accordance with findings of Patil et al (2004).
Improvement in these parameters might be due to the
secretion of ammonia into the rhizosphere in the presence
of root exudates, which helps to modify nutrient uptake by
plants, thus maximizing shoot number, fruit size and
ultimately, the yield (Harikrishna et al, 2002; Sengupta et
al, 2002). Another reason may be the accelerated mobility
of photosynthates from source to sink as influenced by
organics and their accumulation in the fruit. This improved
translocation was possible perhaps due to better sink capacity
resulting in higher number of fruits per plant.

In conciusion, effect of integrated nutrient
management on growth and yield of Cape gooseberry shows
that the integrated use of biofertilizers, organic manures and
chemical fertilizers in combination at an appropriate time,
could help in achieving the goal of high fruit yield and safe
environment and pave the way for sustainable fruit
production. Thus, integrated nutrient management strategy
utilizes a judicious combination of biofertilizers, inorganic
fertilizers and organic manures to bring about improvement
in soil fertility and helps in protecting the environment and
producing higher crop yields than when applied singly.

REFERENCES
Awasthi, R.P., Godara, R.K. and Kaith, N.S. 1998.

Interaction effect of VA mycorrhizae and
Azotobacter inoculation on micronutrient uptake by
peach seedling. Hort. J., 11:1-5

Bhattacharya, P., Jain, R.K. and Paliwal, M.K. 2002.
Biofertilizers for vegetables. Ind.Hort.,  44:12-13

Harikrishna, B.L., Channal, H.T., Hebsur, N.S., Dharmatti,
P.R. and Sarangamath, P.A. 2002. Integrated Nutrient
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Kumar, M., Singh, S., Sharma, S.K., Dahiya, D.S. and
Beniwal, L.S. 2006. Effect of biofertilizers on growth

Table 1. Effect of integrated nutrient management strategies on growth and yield of Cape gooseberry

Treatment Plant Plant spread Plant spread Stem Leaf area Shoot Days to Fruit
height (cm) N-S (cm) E-W  (cm) thickness (cm) (sq. cm) number /plant fruit picking yield/ plant

T
1

85.10 40.00 44.70 1.06 44.90 10.00 210.33 363.63
T

2
82.89 39.90 40.86 1.03 41.01 9.33 211.00 313.33

T
3

80.50 37.13 45.20 1.01 43.16 8.00 208.66 303.30
T

4
91.50 41.33 46.09 1.06 46.59 9.66 200.16 359.00

T
5

88.19 41.13 45.20 1.07 44.41 10.00 216.00 331.00
T

6
93.40 42.41 46.80 1.10 47.45 11.66 213.00 347.33

T
7

94.00 42.10 47.40 1.14 48.15 10.66 204.00 386.60
T

8
99.30 44.13 49.00 1.20 50.01 10.66 207.33 450.00

T
9

114.80 46.70 51.09 1.31 52.65 11.66 203.33 407.30
T

1 0
107.40 45.20 50.33 1.25 51.18 11.33 202.66 431.00

T
1 1

103.10 44.80 49.80 1.22 50.34 11.00 206.00 420.10
T

1 2
97.60 43.03 48.03 1.16 49.36 11.00 205.66 398.20

T
1 3

98.00 43.59 48.53 1.18 48.98 11.00 209.00 371.90
T

1 4
136.50 53.90 63.00 1.43 56.59 16.00 198.00 512.00

T
1 5

133.10 50.00 59.06 1.42 58.13 14.66 192.00 501.40
T

1 6
130.50 48.13 60.59 1.40 54.31 13.33 194.66 483.10

T
1 7

123.40 50.76 55.33 1.37 55.40 11.66 197.00 469.00
T

1 8
119.50 48.83 53.00 1.36 54.01 12.66 194.33 450.30

T
1 9

112.30 46.00 50.90 1.28 53.80 11.66 200.00 491.90
T

20 
(Control) 90.80 39.03 40.33 1.08 45.75 10.33 218.00 334.80

CD (P=0.05) 15.39 8.77 11.59 0.13 3.74 2.93 7.75 19.75
CV% 8.95 11.95 13.94 6.74 4.55 15.71 2.29 2.94
SEm± 5.37 3.06 4.02 0.04 1.30 1.02 2.70 6.90

Integrated nutrient management in Cape gooseberry

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(MS Received 23 November 2010, Revised 25 March 2011)

Sandhu and Gill

J. Hortl. Sci.
Vol. 6(1):29-32, 2011