THAI NGUYEN UNIVERSITY OF AGRICULTURE AND FORESTRY
NGUYEN SON HA
REDUCING THE CHILLING INJURY ON WATER SPINACH (IPOMOEA
AQUATIC) BY USING THE LOW LIGHT TREATMENT WITH SHADE NET
BACHELOR THESIS
Study Mode: Full-Time
Major: Environmental Science and Management
Faculty: The Advanced Education Program
Batch: 2014 – 2018
Thai Nguyen, 09/25/2018
DOCUMENTATION PAGE WITH ABSTRACT
Thai Nguyen University Of Agriculture And Forestry
Degree Program:
Bachelor of Environmental Science and Management
Student name:
Nguyen Son Ha
Student ID:
DTN 1454290010
REDUCING THE CHILLING INJURY ON WATER SPINACH
Thesis Title:
(IPOMOEA AQUATIC) BY USING THE LOW LIGHT
TREATMENT WITH SHADE NET
This report is a part of 100495 Cooperative Education in Agriculture
Assist. Professor I – Chun Pan, National Chung Hsing
Supervisor (s):
University, Taiwan.
Dr. Nguyen Thanh Hai - Thai Nguyen University of Agriculture
and Forestry, Vietnam.
Abstract:
Water spinach (Ipomoea aquatic), one of the most sensitive vegetables with
temperature, faced the cold growing condition as the first time in Taiwan, that brings
many negative impacts to the farmers. The aim was defined the hazard of the chilling
injury (CI) with the critical low temperature and time as well as finding a potential
treatment within shade net to reduce the CI on water spinach. The growth plants were
transferred to the growth chamber at 6oC, 8oC and 10oC for 6 hours before using the
electronical conductivity (EC), leaf color and 1, 1-diphenyl-2-picrylhydrazyl (DPPH)
radical scavenging to estimate the chilling injury index by comparing the samples in
normal light- growing condition with the low light-growing condition with shade net.
i
The results indicate that at 6oC with shade net, water spinach had the lowest EC and
DPPH while the converse was true for 10oC. Hence, the low light treatment by using
shade net is potential and available to apply for reducing the chilling injury.
Key-words:
Water spinach, chilling injury, shade net, EC, DPPH.
Number of pages:
36
Date of submission:
09/25/2018
Supervisor’s
signature
ii
ACKNOWLEDGEMENTS
I would like firstly to emphasize the sincere appreciation to lecturers in the
Advanced Education Program as well as lecturers in Thai Nguyen University of
Agricultural and Forestry, who have lectured me profound knowledge not only for my
subjects but also for my soft skills and gave me a chance to do my thesis abroad. In
addition, I would like to thank all supports and help from Department of Horticulture,
National Chung Hsing University for the time I conducted my research in Taiwan.
It is my pleasure to work with a profound supervisor – Assistant Professor I –
Chun Pan, who always helped me any time. She also gave me the best conditions,
supported all materials for my research and discussed any problems I got whenever I
did experiments in her Molecular Physiology Laboratory.
I would like to give special thanks to Dr. Nguyen Thanh Hai, who always
supported and cheered me up whole the time I worked oversea. He also helps me a lot
in spending much time checking my thesis report.
I consider it is an honor to work with Ms. Nicole, who particularly helpful in
guiding me toward a qualitative methodology and inspiring me for the whole period of
internship time. She is always helpful, friendly and very kind to me. Without her
guidance, I cannot accomplish this thesis.
Finally, I would like to express my gratitude to my family and friends, who
always beside me all the time. Their help supports and encouragements created the
pump leading me to success.
Sincerely,
Nguyen Son Ha
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TABLE OF CONTENTS
DOCUMENTATION PAGE WITH ABSTRACT .........................................................i
ACKNOWLEDGEMENTS ......................................................................................... iii
TABLE OF CONTENTS ..............................................................................................iv
LIST OF FIGURES .......................................................................................................vi
LIST OF TABLES ...................................................................................................... vii
LIST OF ABBREVIATIONS .................................................................................... viii
PART 1: INTRODUCTION ........................................................................................ 1
1.1. Research Rationale .................................................................................................. 1
1.2. Research’s Objectives ............................................................................................. 3
1.3. Research’s questions and hypothesis....................................................................... 3
1.4. Definitions ............................................................................................................... 4
PART 2: LITERATURE REVIEW ............................................................................ 5
2.1. Water spinach: ......................................................................................................... 5
2.1.1: Cultivation Characteristics ................................................................................... 5
2.1.2: Chemical composition, nutritive and medicinal value ......................................... 5
2.1.3: Antioxidant activity .............................................................................................. 7
2.1.4: Water spinach in Taiwan ...................................................................................... 8
2.2: Chilling injury (CI) .................................................................................................. 9
2.2.1: Symptoms of chilling injury ................................................................................. 9
2.2.2: Mineral nutrition................................................................................................. 10
2.2.3: Light and Photosynthesis.................................................................................... 11
2.2.4: Cell membrane changes...................................................................................... 12
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PART 3: MATERIALS AND METHODS .............................................................. 14
3.1: Materials ................................................................................................................ 14
3.1.1 List of instruments ............................................................................................... 14
3.1.2. List of chemicals................................................................................................. 15
3.1.3: Design ................................................................................................................. 16
3.2: Methods ................................................................................................................. 17
3.2.1: Electrical Conductivity Measurements (EC)...................................................... 17
3.2.2: Analysis of the leaf color.................................................................................... 18
3.2.3: Evaluating the damage level of water spinach under chilling stress after three
recovering days. ............................................................................................................ 18
3.2.4: Determination of antioxidant activity by DPPH- scavenging assay .................. 19
3.2.5: Statistical design ................................................................................................. 20
PART 4: RESULTS AND DISCUSSION ................................................................ 21
4.1: Electrolyte leakage ................................................................................................ 21
4.2: Leaf color............................................................................................................... 23
4.3: Damage level ......................................................................................................... 24
4.4: Scavenging Activity of DPPH radicals ................................................................. 28
PART 4: CONCLUSION ........................................................................................... 31
REFERENCES ........................................................................................................... 32
v
LIST OF FIGURES
Figure1: Effect of different treatments on cell membrane permeability of water
spinach after 6hrs in different temperatures. .................................................................21
Figure2: Effect of different treatments on cell membrane permeability of water
spinach at particular temperatures after 6hrs. (a) In the normal light condition; (b) in
the low light condition within shade net........................................................................23
Figure 3: The symptom of chilling injury on water spinach during the period: (a) after
6hrs treatment, (b) after three- recovering days and (c) control group. ........................26
Figure 4: The damage level of chilling on water spinach after three recovering day ...27
Figure 5: DPPH radical scavenging activity of water spinach extracts. .......................29
Figure 6: DPPH radical scavenging activity of water spinach extracts at particular
temperatures after 6hrs. (a) In the normal light condition; (b) in the low light condition
within shade net. ............................................................................................................30
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LIST OF TABLES
Table 1: Nutritional value per 100 g (3.5 oz) of Water spinach, raw (USDA Nutrient
Database) .........................................................................................................................6
Table 2. The list of the vegetables, sensitive to chilling temperatures, the lowest safe
storage/handling temperature and the symptoms of chilling injury (DeEll, 2004). ......10
Table 3.1: Name and commercial company of all instruments used in this study........14
Table 3.2: Properties of liquid nitrogen .........................................................................15
Table 3.3: Properties of methanol .................................................................................15
Table 3.4: Properties of 1, 1-diphenyl-2-picrylhydrazyl (DPPH) .................................16
Table 3.5: Severity level of Chilling injury ..................................................................19
Table 4: The changes of leaf color after 6hrs in different temperatures. ......................24
Table 5: The distribution of damage level on the leaf surface of water spinach of
different treatments at particular temperatures after three recovering days. .................28
vii
LIST OF ABBREVIATIONS
CI
Chilling injury
a*
Chromaticity coordinate (redness or greenness)
b*
Chromaticity coordinate (blueness or yellowness)
L*
Chromaticity coefficient (lightness)
°C
Degrees Celsius (unit for temperature measurement)
g
Grams (unit of Mass)
hrs
Hours (unit of time)
CK
Control condition
DPPH
1, 1-diphenyl-2-picrylhydrazyl
viii
PART 1: INTRODUCTION
1.1. Research Rationale
According to FAO, United Nation report 2002, the world agricultural growth
has slowed down from an average 2.2 percent annually over the past 30 years to 1.5
per cent year until 2030. On the other hand, the world population growth will be
growing at an average of 1.1 percent a year up to 2030, compared to 1.7 percent
annually over the past 30 years. This will put an increased pressure on producing more
food to fulfill the requirement of the growing population all over the world. Fruit and
vegetable production is lower than grain production; however, they contribute
important nutrients to the diet, including vitamins A and C, folic acid, potassium, and
dietary fiber.
Among many types of vegetables, Leafy vegetables, such as Kale, Swiss chard,
Water spinach, Cabbage, play an important role in Asian daily diet because of their
nutritional and medical value. Green leafy vegetables occupy an important place
among food crops as these provide adequate amounts of crude fiber, carotene, a
precursor of vitamin A, vitamin C, riboflavin, folic acid and mineral salts like calcium,
iron, phosphorus etc. They form cheap and best source of food. Green leafy vegetables
are highly seasonal and are available in plenty at a particular season and can be easily
cooked.
In recent years, climate change is a “hot” issue in the world. It becomes more
and more seriously day by day. Hence, Climate change affects directly on agriculture,
especially on the cultivation of vegetables. Little change in the climate will disturb the
whole ecology and in-turn the traditional pattern of growing vegetables. Vegetables
1
are generally sensitive to environmental extremes. Extreme variation in temperature
and limited soil moisture are the major causes of low yields as they greatly affect
several physiological and biochemical processes like reduced photosynthetic activity,
altered metabolism and enzymatic activity, thermal injury to the tissues, reduced
pollination and fruit set etc. These will further be magnified by climate change which
can exact a heavy toll on the vegetable production. Under changing climatic situations,
crop failures, shortage of yields, reduction in quality and increasing pest and disease
problems are common, which render the vegetable cultivation unprofitable
(Koundinya et al., 2014).
In Taiwan, vulnerable area to climate change, Water spinach (Ipomoea aquatic)
has become an important leafy vegetable because of storm-tolerant rain, rapid growth
and high yields beside their nutritional, medical value. According to statistics from
Taiwan's Agricultural Annual Report, the cultivated area is more than 2,000 hectares
per year. Nevertheless, the cultivation of Water spinach has been facing up to CI
(Chilling injury) for the first time. The production and quality of Water spinach,
reduced by CI became a new challenge for Taiwanese farmers. Therefore, it is
important to establish treatments that can reduce CI of Water spinach. There are
several techniques are available to either reduce the development of CI symptoms or
increase the resistance to CI such as heat-treatment, intermittent warming, controlled
atmosphere storage, treatments with calcium, chemicals, waxing, film packaging,
genetic modification, and applications with ethylene, abscisic acid, polyamines, or
other natural compounds. However, these treatments are not suitable and economical
2
for the condition of cultivating Water spinach in Taiwan because most of its products
have been cultivated in the fields which directly are under the climate change effects.
Therefore, in this research, the low light treatment by using the shade nets
which is easy to apply on the fields and has economic value for the farmers was used
to lessen the effects of light, an important factor on Photosynthesis process, for
avoiding the impacts of Chilling injury on Water spinach.
1.2. Research’s Objectives
The main purpose of this research is to evaluate the potential of low light
treatment by using the Shade nets for preventing the Chilling injury on Water spinach
as well as other vegetables.
1.3. Research’s questions and hypothesis
• Research’s questions:
Is there any impact of chilling temperature on water spinach?
Which temperature affects significantly water spinach?
What are the differences between normal light treatment and low light
treatment with shade net?
Is it possible to apply shade net as a solution for farmers?
• Research’s hypothesis:
Null hypothesis: there is no significant difference between normal light
treatment and low light treatment with shade net
Alternative hypothesis: there are significant difference between normal light
treatment and low light treatment with shade net. Therefore, Shade net is possible to
avoid chilling injury on water spinach.
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1.4. Definitions
• Water spinach (Ipomoea aquatic) is a member of the Convolvulaceae
(Morning glory) family and the same genus as the sweet potato (Ipomoea batatas).
Water spinach is an herbaceous aquatic or semi-aquatic perennial plant of the tropics
and subtropics (Wikipedia, 2005).
• Chilling
injury
(CI)
is
damage
to
plant
parts
caused
by
temperatures above the freezing point (32°F, 0°C). Plants of tropical or subtropical
origin are most susceptible. Chilling injured leaves may become purple or reddish and
in some cases wilt. Both flowers and fruit of sensitive species can be injured.
4
PART 2: LITERATURE REVIEW
2.1. Water spinach:
2.1.1: Cultivation Characteristics
Water spinach will grow in a slightly acidic (5.5-7.5) and fertile soil rich in
organic matter. Water spinach is not adapted to climates with mean temperatures
below 10°C and the optimal temperature is around 20°C – 30°C. It is grown yearround in the tropics. Flowering occurs under short-day conditions and commences
from mid-summer onwards. Water spinach is perennial in warm climates, but an
annual under cooler growing conditions. It tolerates very high rainfall, but not frost.
Water spinach can be grown outside in summer. In cool areas, it can be grown in
unheated greenhouses in summer, but will require heated greenhouses for a spring
crop. It prefers full sun but where summer temperatures are very high, it is sometimes
grown as a ground cover beneath climbing plants. Water spinach should be sheltered
from strong winds (Rubatzky, V. (1990)).
2.1.2: Chemical composition, nutritive and medicinal value
Water spinach is ranked among world’s healthiest food. During the 1930’s
and post it, the vegetable became widely loved and demanded in the market by
parents as well as kids after the famous comic and cartoon Popeye. This is a rich
source of nutrients, vitamins and minerals that are highly beneficial for skin eyes
and brain. The spinach contains abundance of water, iron, vitamin C and Vitamin A
among other rich nutrients. This leaf is also a source of calcium and fiber. Water
spinach helps us keep ourselves healthy and young complemented with beautiful
and radiant skin and strong teeth bones and hair. It reduces cholesterol, cures
5
anemia, controls diabetes, treats jaundice and liver problems, increases metabolism
and provides solution for constipation and indigestion, helpful for heart disease
patients, prevents cancer, beneficial for eyes, rejuvenates skin and maintains
healthy scalp and hair, also famous for its anti-ageing benefits.
Table 2.1: Nutritional value per 100 g (3.5 oz) of Water spinach, raw (USDA
Nutrient Database)
Nutrient
Proximates
Water
Energy
Protein
Total lipid (fat)
Carbohydrate, by
difference
Fiber, total dietary
Minerals
Calcium, Ca
Iron, Fe
Magnesium, Mg
Phosphorus, P
Potassium, K
Sodium, Na
Zinc, Zn
Vitamins
Vitamin C, total ascorbic
acid
Thiamin
Riboflavin
Niacin
Vitamin B-6
Folate, DFE
Vitamin B-12
Vitamin A, RAE
Vitamin A, IU
Vitamin D (D2 + D3)
Vitamin D
Lipids
Fatty acids, total trans
Cholesterol
Unit
1Value per 100
g
1 cup, chopped =
56.0g
1 shoot =
13.0g
g
kcal
g
g
92.47
19
2.6
0.2
51.78
11
1.46
0.11
12.02
2
0.34
0.03
g
3.13
1.75
0.41
g
2.1
1.2
0.3
mg
mg
mg
mg
mg
mg
mg
77
1.67
71
39
312
113
0.18
43
0.94
40
22
175
63
0.1
10
0.22
9
5
41
15
0.02
mg
55
30.8
7.2
mg
mg
mg
mg
µg
µg
µg
IU
µg
IU
0.03
0.1
0.9
0.096
57
0
315
6300
0
0
0.017
0.056
0.504
0.054
32
0
176
3528
0
0
0.004
0.013
0.117
0.012
7
0
41
819
0
0
g
mg
0
0
0
0
0
0
6
Besides, Water spinach is highly effective in treating ulcers, menstrual pains,
toothache, urination, nosebleed etc. It also acts as a sedative for people suffering
from insomnia or sleeping difficulty (Burkill, 1966). Its juice mixed with water is
usable as a cold compress to treat fever. Being anti-venom, it is in use to promote
vomiting in case of poisoning. It treats skin diseases such as ringworm; athlete’s
foot etc. helps in the prevention of skin cancer and is usable in the treatment of
acne, eczema and psoriasis. Due to its healing and detoxifying properties, it helps
in providing relief in case of skin itching or insect bites.
2.1.3: Antioxidant activity
It is by now commonly accepted that under situations of oxidative stress,
reactive oxygen species such as superoxide (O2·-), hydroxyl (OH·-), and peroxyl
(· OOH, ROO· ) radicals are generated. These reactive oxygen species play an important
role in degenerative or pathological processes, such as aging (Burns et al., 2001),
cancer, coronary heart disease, Alzheimer's disease (Ames, 1983), neurodegenerative
disorders, atherosclerosis, cataracts, and inflammation (Aruoma, 1998). The use of
traditional medicine is widespread, and plants are still a large source of natural
antioxidants that might serve as leads for the development of novel drugs. Several antiinflammatory, digestive, antinecrotic, neuroprotective, and hepatoprotective drugs
have recently been shown to have an antioxidant and/or radical scavenging mechanism
as part of their activity (Perry et al., 1999; Lin and Huang, 2002; Repetto and Llesuy,
2002). In searching for novel natural antioxidants, some plants have been extensively
studied in the past few years for their antioxidant and radical scavenging components.
These include echinacoside in Echinaceae root (Hu and Kitts, 2000), anthocyanin
7
(Espin et al., 2000), phenolic compounds (Rice-Evans et al., 1997), water extracts of
roasted Cassia tora (Yen and Chuang, 2000), and whey proteins (Allen and Wrieden,
1982).
The aquatic plant water spinach (Ipomoea aquatica Forsk) grows wild and is
cultivated throughout Southeast Asia and is a widely consumed vegetable in the
region. Many of the waters where I. aquatica grows serve as recipients for domestic
and other types of waste water. Because these waters contain not only nutrients, but
often also a wide variety of pollutants, such as heavy metals from various human
activities, many people risk poisoning. Water spinach is also supposed to possess an
insulin-like activity according to indigenous medicine in Sri Lanka (Malalavidhane et
al., 2000).
2.1.4: Water spinach in Taiwan
In Taiwan, they turned this wild plant into an important cultivated vegetable
crop. Mainland people were settling on the island of Taiwan by A.D. 1167 and maybe
before. Taiwan is dominated by dry land and aquatic cultivation. The drylands are
cultivated throughout the province, mainly in Taipei, Taoyuan, Taichung, Changhua,
Nantou, Yunlin, Chiayi, Tainan and Pingtung. Aquatic cultivation is mainly carried
out in Jiaoxi Township of Yilan County, Dali City and Wufeng Township of Taizhong
County, Ming Jian Township and Zhushan Township of Nantou County. Because of
its high heat resistance and moisture resistance, it grows rapidly in the hot and humid
seasons and can be harvested from 18 to 28 days after sowing. In the past, during the
growth period, it was less likely to be harmed by small gold flower worms and white
8
rust, and few other pests occurred. Therefore, it can be harvested about 10 times a year
in Taiwan.
2.2: Chilling injury (CI)
2.2.1: Symptoms of chilling injury
Vegetables are sensitive to chilling and after prolonged storage in these
temperatures external symptoms of injury are developed and death of the organism
occurs (Table1). Plants, which have the visual injuries at temperatures above 15°C, are
called “very sensitive to chilling” (Raison, Lyons, 1986). A number of tropical or
subtropical plants, such as rice, maize, tomato, cucumber, cotton, soybeans, etc.,
introduced in the higher latitudes have not acquired substantial resistance to chilling,
despite the long history of cultivation in temperate regions (Wilson, 1985).
According to Skog (1998), potential symptoms of chilling injury are surface
lesions, water soaking of tissues, water loss, desiccation or shriveling, internal
discoloration, tissue breakdown, failure of fruit to ripen, or uneven or slow ripening,
accelerated senescence and ethylene production, shortened storage or shelf life,
compositional changes, loss of growth or sprouting capability, wilting and increased
decay due to leakage of plant metabolites, which encourage growth of
microorganisms, especially fungi.
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Table 2.2. The list of the vegetables, sensitive to chilling temperatures, the lowest safe
storage/handling temperature and the symptoms of chilling injury (DeEll, 2004).
Crop
Asparagus
Bean ( snap)
Lowest safe temperature °C
0-2
7
Chilling injury symptoms
Dull, gray-green, limp tips
Pitting and russeting
Cucumber
7
Eggplant
7
Okra
7
Pepper
7
Potato
2
Pumpkin
10
Squash
10
Sweet potato
10
Tomato( ripe)
7-10
Tomato ( maturegreen)
13
Pitting, water- soaked
lesions, decay
Surface scald, alternaria rot,
seed blackening
Discoloration, water-soaked
areas, pitting, decay
Pitting, alternaria rot, seed
blackening
Mahogany browning,
sweetening
Decay, especially alternaria
rot
Decay, especially alternaria
rot
Decay, pitting, internal
discoloration
Water-soaking, softening,
decay
Poor color when ripe,
alternaria rot
2.2.2: Mineral nutrition.
Low temperatures have an effect on mineral nutrition of plants. Absorption of
ions by roots is difficult, as well as their movement in the aboveground parts of plants.
The distribution of nutrients between the plant organs is disrupted, with the general
decrease in the nutrient content in the plant. Chilling of plants leads to a decrease in
the activity of nitrate reductase, reduction in the nitrogen incorporation in the amino
10
acids and proteins, and a drop in the proportion of organic phosphorus and an increase
in inorganic P content (Holobrada et al., 1981; Zia et al., 1994), which is a
consequence of a breach of phosphorylation and enhanced decomposition of organic P
compounds. Mechanisms to reduce the absorption of nutrients by chilling temperatures
include depression of respiration and/or oxidative phosphorylation, impair enzymatic
transport systems acted with conformational proteins changes in membranes, changes
in membrane potential, reducing the supply of ATP to H+-transporting ATPase, as
well as lowering the permeability coefficients for ions (Alexander S. LUKATKIN et
al., 2012).
2.2.3: Light and Photosynthesis
During and after chilling, the rate of photosynthesis in the leaves of chilling
sensitive plants decreased and this is more related to decreasing temperature and
lengthening of chilling period and persisted for a long time after transfer of chilled
plants in the heat. The physiological reasons for the suppression of photosynthesis are
the inhibition of phloem transport of carbohydrates from the leaves, stomatal
limitation, destruction of the photosynthetic apparatus, damage to water-splitting
complex of photosystem I, inhibiting electron transport, and uncoupling of electron
transfer and energy storage, changes in the activity and inhibition of synthesis of key
enzymes of the Calvin cycle and C4-way (Yordanov, 1992). Cold-sensitive crop
species have smaller temperature homeostasis of leaf photosynthesis than cold-tolerant
species.
Chilling of sensitive plants in light had much stronger effects on the
photosynthetic apparatus than chilling in the dark (Alam, Jacob, 2002). It is considered
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