Evaluation of Vegetative Growth and Total Chlorophyll of Four
Sweet Potato Genotypes in the Highland and Lowland
Darma Bakti
1
, Rosmayati
1,2
and Nini Rahmawati
1,2
1
Faculty of Agriculture, Universitas Sumatera Utara, Padang Bulan, Medan 20155, Indonesia
2
Centre for Roots and Tuber Studies Universitas Sumatera Utara
{darma, rosmayati, nini }@usu.ac.id
Keywords: Sweet potato, vegatative growth, chlorophyll, higland and lowland
Abstract: Sweet potato crop productivity is influenced by several factors such as the growing season, soil type,
irrigation system, plant propagation materials, use of genotypes, plant nutrition and others. The objective of
this study was to evaluation of vegetative growth and total chlorophyll of four sweet potato genotypes in the
highland and lowland. Field experiment was conducted on April – July 2018 was arranged in a randomized
block design with two factors, the first factor is the genotypes of sweet potato (UbiSibolu accession from
SaribuDolok Village Simalungun, UbiSibolu accession from Kasemak Village Simalungun and UbiSibolu
accession from BatangBeruh Village and Beta – 1 variety). The second factor was altitude of planting area
(highland 1440 MSAL and lowland 28 MSAL). The result showed three local sweet potato genotypes from
upland areas in Simalungun Regency and DairiRegency Sumatera Utara have the ability to adapt and grow
well in the lowland and in the highland which are not their origin compared to varieties Beta-2 which is a
national superior variety. Vegetative growth of four sweet potato genotypes is better in the lowland than in
the highland.
1 INTRODUCTION
Sweet potatoes are an important food crop in the
world (Šlosár et al., 2016). Among the tuber groups,
sweet potatoes are one of the potential local food
ingredients to be developed in the future. It is based
on the consideration that sweet potatoes are the
fourth source of carbohydrates after rice, maize, and
cassava; have high productivity potential; have
diversified product diversity potential; has a diverse
nutritional content, and has the potential market
demand both local, regional, and exports are
increasing (Šlosár et al., 2016; Laban et al., 2015;
Ahmad et al., 2011).
Growth and development of plants is influenced
by external and internal factors. External factors
include soil, humidity, air, temperature, light and
water. Internal factors may include genes, hormones,
chlorophyll content as well as morphological and
anatomical structures of plant organs (Widya, 2015).
Environmental factors are an important
consideration in the selection of plants or locations
for more productive crop cultivation. Plant growth
and development are significantly affected by
elevation and altitude. In addition, environmental
factors also affect the ability of plants to adapt
(Krishania et al., 2013; Nayak and Altekar, 2015;
Maria and Rodica, 2015
Sweet potato crop productivity is influenced by
several factors such as the growing season, soil type,
irrigation system, plant propagation materials, use of
genotypes, plant nutrition and others. Identification
of accession groups with excellent production
potential is a population of the sweet potato genetic
development program in the future (Vargas et al.,
2017). Sumatera Utara is one of the centers of sweet
potato production in Indonesia. Research on the
exploration and identification of sweet potatoes in
Sumatera Utara shows various types of sweet
potatoes from various accessions with a variety of
different characters. These local sweet potato
genotypes have the potential to be developed for
assembly of sweet potato varieties that have wide
adaptability (Rosmayati and Bakti, 2018).
Sweet potatoes are plants that have wide
adaptability. Determining the appropriate location is
very important to consider to get maximum tuber
yield. Sweet potatoes can be planted in areas with a
height of 0 - 3000 MASL and maximum tuber
formation at a temperature of 25°C at night, this
Bakti, D., Rosmayati, . and Rahmawati, N.
Evaluation of Vegetative Growth and Total Chlorophyll of Four Sweet Potato Genotypes in the Highland and Lowland.
DOI: 10.5220/0010097200930097
In Proceedings of the International Conference of Science, Technology, Engineering, Environmental and Ramification Researches (ICOSTEERR 2018) - Research in Industry 4.0, pages
93-97
ISBN: 978-989-758-449-7
Copyright
c
2020 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
93
indicates environmental factors such as light and
temperature are very important to consider
(Sulistiani et al., 2018)
The objective of this study was to evaluation of
vegetative growth and total chlorophyll of four
sweet potato genotypes in the highland and lowland
as preliminary data to determine environmental
suitability and adaptability of sweet potato
genotypes.
2 MATERIALS AND METHODS
Field experiment was conducted on April – July
2018 at the experimental farm in Balai Penelitian
Tanaman Sayuran Tongkoh – Berastagi (1440
MASL) and Cengkeh Turi Village Binjai (28
MASL), chlorophyll analysis is carried out in
Tissue Culture Laboratory Faculty of Agriculture
Universitas Sumatera Utara. Materials and tools
used in this study include sweet potato stem cuttings,
fertilizer, aquades, 80% acetone, erlenmeyer, filter
paper, UV-VIS spectrophotometer and label.
A randomized block design with two factors with
three replications was employed. The first factor was
the genotypes of sweet potato (UbiSibolu accession
from SaribuDolok Village Simalungun, UbiSibolu
accession from Kasemak Village Simalungun and
UbiSibolu accession from BatangBeruh Village and
Beta – 1 variety). The second factor was altitude of
planting area (highland 1440 MSAL and lowland 28
MSAL). The research stages include land
preparation, making beds, planting, fertilizing using
urea, TSP and KCl fertilizer, maintenance and
parameter observation. The observation on vine
length, number of branch, number of leaves, fresh
vine weight were collected in the fifth and tenth
weekss after planting, while chlorophyll total were
observed in the tenth weeks after planting.
Data analysis using analysis of variance
(ANOVA). Duncan Multiple Range Test (DMRT)
was used to separate means at 5% level of
probability. Please remember that all the papers
must be in English and without orthographic errors.
3 RESULTS AND DISCUSSION
Plant morphology is influenced by environmental
conditions and genetic factors. Both factors will
interact during the life cycle of the plant and so that
plant phenotypes appear that are similar to each
other or completely different. If environmental
influences are dominant compared to genetic,
morphological variations may occur from the same
species (Suranto, 2002). The results showed that the
morphological appearance and vegetative growth of
four sweet potato genotypes showed significant
differences in vine length, number of leaves and fesh
vine weight (Table 1 and Table 3).
Table 1.Vine length and branch number of four sweet
potato genotypes on 5 and 10 weeks after planting
Genotype Five weeks after
p
lanting
Ten weeks after
p
lanting
Vine
lenght
(
cm
)
Branch
number
(
branch
)
Vine
lenght
(
cm
)
Branch
number
(
branch
)
Ubi Sibolu
Saribu Dolo
k
125,83 a 5,50 238, 33 a 8,83
Ubi Sibolu
Kasema
k
104,50 a 5,17 223,00 ab 8,67
Ubi Sibolu
Batang
Beruh
106,00 a 5,17 223,50 ab 8,33
Beta – 1
variet
y
79,83 b 4,83 207 b 8,50
Note : Mean values followed different letter in the same
column is significantly difference based on DMRT at α =
5% .
The vegetative growth of genotipeSibolu with
accession of SaribuDolok Village Simalungun is
higher than the other two local genotypes, they were
Sibolu with accession Kasemak Village Simalungun
Village and Sibolu with accession BatangBeruh
Village, Dairi which can be seen from all observed
growth parameters. Whereas the vegetative growth
of sweet potato of national superior variety Beta-2 is
the lowest compared to the three local genotypes.
This condition is suspected because the local
genotype has the ability to adapt better to an
environment similar to its original accession.
Environmental similarities, namely climatic and soil
conditions support the growth and development of
local genotypes better than invasive genotypes
(Boshier et al., 2015; Zen and Syarif, 2013). Each
plant genotype requires an environment suitable for
its growth and development (Chen et al., 2015).
ICOSTEERR 2018 - International Conference of Science, Technology, Engineering, Environmental and Ramification Researches
94
Table 2. Vine length and branch number of sweet potatoes
on highland and lowland on 5 and 10 weeks after planting
Altitude Five weeks after
p
lantin
g
Ten weeks after
p
lantin
g
Vine
lenght
(
cm
)
Branch
number
Vine
lenght
(
cm
)
Branch
number
Lowland
(28 MSAL)
137,33 a 5,33 277,67 a 8,67
Highland
(1440 MSAL)
70,75 b 5,00 168,25 b 8,50
Note : Mean values followed different letter in the same
column is significantly difference based on DMRT at α =
5%.
Sweet potato vegetative growth is strongly
influenced by environmental factors. The results of
the study showed that there were significant
differences in the parameters of vine length, number
of leaves and fresh vine weight of sweet potato
grown in the lowlands and highlands (Table 2 and
Table 4). Previous research also showed that sweet
potatoes grown in the lowlands had longer vines
than those in the highlands (Sulistiani et al., 2018).
This condition is thought to be due to differences in
temperature and rainfall in the lowlands and
highlands. The average temperature in lowland
during April – Juli 2018 in the day 27°C, 22°C in
night and average rainfall was 159.5 mm, while in
the highlands daytime temperatures were 24°C,
14°C in nite and rainfall during the study was 147.8
mm (Data.org, 2018).
Table 3. Number of leaves and fresh vine weight of four
sweet potato genotypes on 5 and 10 weeks after planting
Genotype Five weeks after
p
lanting
Ten weeks after
p
lanting
Number
of leaves
Fresh vine
wei
g
ht
(g)
Number of
leaves
Fresh vine
wei
g
ht
(g)
Ubi Sibolu
Saribu
Dolo
k
62,83 a 259,83 a 146,33 a 644,83 a
Ubi Sibolu
Kasema
k
59,17 ab 210,83 b 141,50 ab 587,67 ab
Ubi Sibolu
Batang
Beruh
54,33 ab 209,50 b 138,50 ab 591,00 ab
Beta – 1
variet
y
53,83 b 204,00 b 137, 17 b 534,67 b
Note : Mean values followed different letter in the same
column is significantly difference based on DMRT at α =
5%
The study of Gajanayake et al. (2015) also
shows an increase in temperature will increase the
length of sweet potato stems. The growth of plants
including sweet potatoes is strongly influenced by
temperature, both air temperature and soil
temperature (Gajanayake et al., 2015; Hatfield and
Prueger, 2015; Ravi et al., 2009). An increase in air
temperature plays an important role in stem
extension, canopy development, and biomass
accumulation (Patel and Franklin, 2009). Optimum
temperature for growth and stem and need leaf area
between 29-30˚C.
Table 4. Number of leaves and fresh vine weight of sweet
potatoes on highland and lowland on 5 and 10 weeks after
planting
Altitude Five weeks after
p
lantin
g
Ten weeks after
p
lantin
g
Number
of leaves
Fresh vine
weight (g)
Number
of leaves
Fresh vine
weight (g)
Lowland
(
28 MSAL
)
59,17 232,33 a 145,00 a 623,17 a
Highland
(1440
MSAL)
55,92 209,75 b 136,75 b 555,92 b
Note : Mean values followed different letter in the same
column is significantly difference based on DMRT at α =
5%
The results showed that the number of leaves and
fresh vine weight were influenced by the genotype
and environment of growing sweet potatoes (Table 3
and Table 4). Number of leaves and fresh vine
weight of local genotypes were higher than those of
superior varieties of Beta-1, and sweet potatoes
grown in the lowlands also had a number of leaves
and fresh vine weight which was higher than in the
highlands. The plant canopy plays an important role
as a source of photosynthate producing which will
determine plant productivity. Leaves are important
plant organs because they contain pigments or
biochromes which play a role in light absorption.
Pigments such as chlorophyll are needed by plants to
absorb light for photosynthesis (Hue et al., 2011).
Chlorophyll content is one of the determinants of
plant growth (Rosmayati and Bakti, 2018)
Evaluation of Vegetative Growth and Total Chlorophyll of Four Sweet Potato Genotypes in the Highland and Lowland
95
Table 5. Total chlorophyll of four sweet potato genotypes
on 5 and 10 weeks after planting
Genotype
Total chlorophyll
(
m
g
/
g)
Ubi Sibolu Saribu Dolo
k
2,02
Ubi Sibolu Kasema
k
2,01
Ubi Sibolu Batang Beruh 1,95
Beta
–
1 variet
y
2,03
Based on statistical analysis, the total
chlorophyll in the sweet potato genoltipe was not
significantly different (Table 5). The highest
chlorophyll total is in Beta - 1 varieties. Chlorophyll
formation is influenced by several factors, namely
plant genetic factors, light intensity, oxygen,
carbohydrates, nutrients, water, and temperature
(Setyanti et al., 2013).
Table 6. Total chlorophyll of sweet potato on five on
highland and lowlandon 5 and 10 weeks after planting
Genotype Total chlorophyll (mg/g)
Lowland (28 MSAL) 2,06 a
Hi
g
hland
(
1440 MSAL
)
1,95 b
Note : Mean values followed different letter is
significantly difference based on DMRT at α = 5%.
The results of the study show that total
chlorophyll is significantly influenced by
environmental factors. The total chlorophyll in sweet
potato leaves cultivated in the lowland is higher than
that of sweet potatoes grown in the highlands (Table
6). Total chlorophyll content in the lowlands
increased by 5.64% compared to the highlands. This
condition is due to the higher light intensity and air
temperature in the lowlands. Chlorophyll formation
is affected by sunlight and air temperature.
Dwidjoseputro (1981) stated that chlorophyll can be
formed in the presence of sunlight which directly
affects plants and 30-40°C temperature is a good
condition for chlorophyll formation in most plants,
but the best is at temperatures between 26-30°C.
4 CONCLUSIONS
Evaluation of vegetative growth and total
chlorophyll parameters shows three local sweet
potato genotypes from upland areas in Simalungun
Regency and DairiRegency Sumatera Utara have
the ability to adapt and grow well in the lowland and
in the highland which are not their origin compared
to varieties Beta-2 which is a national superior
variety. Vegetative growth of four sweet potato
genotypes is better in the lowlands than in the
highlands.
ACKNOWLEDGEMENTS
This research is part of the research supported by
Universitas Sumatera Utara through the scheme
TALENTA USU 2018 with contract number: 2590 /
UN5.1.R / PPM / 2018, 16 March 2018. The author
would like to thank for the financial support and
facilities for this research.
REFERENCES
Ahmad, F. M., Ashraf, A. S., Ahmad, A. F., Ansari, A. J.,
Siddiquee, M. R., 2011. Nutraceutical market and its
regulation. American Journal of Food Technology
Vol. 6 (5) pp. 342-347.
Boshier, D., Broadhurst, L., Cornelius, J., Gallo, L.,
Koskela, J., Loo, J., Petrokofsky, G. and Clair, B.S.
2015. Is local best? Examining the evidence for local
adaptation in trees and its scale. Environ Evid 4 (20)
pp. : 1 – 10x
Chen, G., Wang, S., Huang, X., Hong, J., Du, L., Zhang,
L., Ye, L., 2015.Environmental factors affecting
growth and development of Banlangen (Radix isatidis)
in China. African Journal of Plant Science Vol. 9 (11)
pp. 421-426
Data.org. 2018.Climate data for cities around the world.
https://id.climate-data.org. Accessed 1 Agust 2018.
Dwidjoseputro, D., 1981.
PengantarFisiologiTumbuhanGramedia Jakarta.
Gajanayake, B., Reddy, K. R., Shankle, M. W.,
2015.Quantifying growth and developmental
Responses of Sweetpotato Mid-and Late-Season
Temperature. Agronomy Journal Vol. 107 (5) : 1854–
1862
Hatfield, J. L., Prueger, J. H. 2015.Temperature extremes :
Effect on plant growth and development Weather and
Climate Extremes. http://dx.doi.org/
10.1016/j.wace.2015.08.001
Hue, S. M., Boyce, A. N., Somasundram, C., 2011.
Influence of growth stage and variety on the pigment
levels in Ipomoea batatas (Sweet potato) leaves.
African Journal of Agricultural Research Vol. 6 (10)
pp. 2379-2385.
Krishania, S., Dwivedi, P., Agarwal, K., 2013.Strategies
of adaptation and injury exhibited by plants under a
variety of external conditions: a short review.
Comunicata Scientiae 4 (2) pp. 103-110
Laban, T. F., Peace, K., Robert, M., Maggiore, K., Hellen,
M., Muhumuza, J., 2015.Participatory agronomic
performance and sensory evaluation of selected
orange-fleshed sweet potato varieties in south western
Uganda. Global J. Sci. Frontier Res., Vol.15 pp. 25-
30.
ICOSTEERR 2018 - International Conference of Science, Technology, Engineering, Environmental and Ramification Researches
96
Maria, D., Rodica, S., 2015. Researches on the sweet
potato (Ipomea batatas L.) behaviour under the soil
and climatic conditions of the South-West of
Romania. Journal of Horticulture, Forestry and
Biotechnology Vol. 19 (1) pp. 79- 84
Nayak G., Altekar, N., 2015. Effect of biofield treatment
on plant growth and adaptation. J. Environ Health Sci
1(2) pp 1-9
Patel, D., Franklin, K. A., 2009.Temperature-regulation of
plant architecture. Plant Signal Behav. 4:577–579.
Ravi, V., Naskar, S., Makeshkumar, T., Babu, B.,
Krishnan, B. S. P., 2009.Molecular physiology of
storage root formation and development in sweet
potato (Ipomoea batatas (L.) Lam.). J Root Crops. 35:
1-27.
Rosmayati., Bakti, D., 2018. Identification and
phylogenetic analysis of local yellow and orange
sweet potatoes genotypes in Sumatera Utara. IOP
Conf. Series: Earth and Environmental Science 122
(2018) 012048 doi :10.1088/1755-1315/122/1/012048
Setyanti, Y. H., Anwar S., Slamet, W., 2013. Karakteristik
fotosintetik dan serapan fosfor hijauan alfalfa
(Medicagosativa) padatinggi pemotongan dan
pemupukan nitrogen yang berbeda. Animal
Agriculture Journal Vol. 2 (1) pp. 86 – 96.
Šlosár, M., Mezeyová, I., Hegedűsová, A. Golian, M.
2016.Sweet potato (Ipomoea batatas l.) Growing in
conditions of Southern Slovak Republic. Scientific
Journal for Food Industry Vol. 10 pp. 384-392
Sulistiani, R., Rosmayati, Siregar, L. A. M., Harahap, F.,
2018. Differences in morphology and sugar content of
purple sweet potato (Ipomoea batatas L.) with
potassium treatment at several altitudes. IOP Conf.
Series: Earth and Environmental Science 122 (2018)
012050 doi :10.1088/1755-1315/122/1/012050
Suranto. 2002. Pengaruh lingkungan terhadap bentuk
morfologi tumbuhan. Enviro 1 (2): 3
Widya, L. N., 2015.Analisis Kandungan Klorofil Daun
Pucuk Merah (Syzygium oleana) pada Warna Daun
yang Berbeda Sebagai Sumber Belajar Biologi SMA
Kelas XI. FKIP UAD Yogyakarta.
Vargas, P. F., Godoy, D. R. Z., de Almeida, L. C. F.,
Castoldi, R., 2017.Agronomic characterization of
sweet potato accessions.Comunicata Scientiae 8(1) pp.
116-125
Zen S., Syarif, A. A., 2013.Peluang Perbaikan varietas
lokal padi gogo Pasaman Barat. Buletin Plasma
Nutfah Vol.19 (1) pp. : 1 -8
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