C O N T E N T S JOURNAL OF HORTICULTURAL SCIENCES Volume 16 Issue 1 June 2021 In this Issue i-ii Review Moringa (Moringa oleifera L.): An underutilized and traditionally valued 1-13 tree holding remarkable potential Jattan M., Kumari N., Raj Kumar, Kumar A., Rani B., Phogat D.S., Kumar, S. and Kumar, P. Original Research in Papers Characterization and evaluation of mountain sweet thorn 14-25 (Flacourtia montana J. Grah) collections Tripathi P.C., Ganeshan S., Radhika V. and Shetti D.L. Optimization of methodology for the extraction of polyphenolic compounds 26-35 with antioxidant potential and á-glucosidase inhibitory activity from jamun (Syzygium cumini L.) seeds Arivalagan M., Priyanka D.R. and Rekha A. Genetic variability studies in amaranthus (Amaranthus spp.) 36-44 Agadi A.H., Kolakar S., Lakshmana D., Nadukeri S. and Hanumanthappa M. Morpho-physiological parameters associated with chlorosis resistance to 45-52 iron deficiency and their effect on yield and related attributes in potato (Solanum tuberosum L.) Challam C., Dutt S., Sharma J., Raveendran M. and Sudhakar D. Responses of different Okra (Abelmoschus esculentus) cultivars to water 53-63 deficit conditions Ayub Q., Khan S.M., Hussain I., Naveed K., Ali S., Mehmood A., Khan M.J., Haq N.U., Shehzad Q. Induced variability for yield and its attributing traits in cluster bean 64-68 [Cyamopsis tetragonoloba (L. ) Taub] through gamma irradiation Lavanya H.N., Mishra S., Sood M., Aghora T.S., Anjanappa M., Rao V.K. and Reddy A.B. In vitro multiplication protocol for Curcuma mangga : Studies on carbon, 69-76 cytokinin source and explant size Waman A.A., Bohra P., Karthika Devi R. and Pixy J. Effect of fungicide and essential oils amended wax coating on quality and shelf life 77-90 of sweet orange (Citrus sinensis Osbeck) Bhandari M., Bhandari N. and Dhital M. Post-harvest quality and quantification of betalains, phenolic compounds and 91-102 antioxidant activity in fruits of three cultivars of prickly pear (Opuntia ficus-indica L. Mill) Gonzalez F.P.H., Saucedo V.C., Guerra R.D., Suarez E.J., Soto H.R.M. Lopez J.A., Garcia C.E. and Hernandez R.G. Soil microbial community dynamics as influenced by integrated nutrient 103-113 management practices in sweet basil (Ocimum basilicum L.) cultivation Baraa AL-Mansour and D. Kalaivanan Effect of spectral manipulation and seasonal variations on cut foliage production 114-120 and quality of Philodendron (Philodendron ‘Xanadu’) Sujatha A. Nair, Laxman R.H. and Sangama Short Communications Studies on mutagenic sensitivity of seeds of pummelo (Citrus maxima Merr.) 121-124 Sankaran M., Kalaivanan D. and Sunil Gowda D.C. Isolation and characterization of microsatellite markers from 125-129 Garcinia indica and cross species amplification Ravishankar K.V., Vasudeva R., Hemanth B., Nischita P., Sthapit B.R., Parthasarathy V.A. and Rao V.R. In this issue… The farmers involved in the production of horticultural produce have defied the challenges due to second wave of the COVID pandemic. Especially, the information that India’s horticulture production is expected to increase by 2.93 per cent to a record level of 329.86 million tonnes (MT) in 2020-21, according to the second advance estimate of horticulture production released by the Ministry of Agriculture is very much motivating. Though many hurdles are faced by the farmers due to the prevailing Covid Pandemic with respect to timely marketing, storage and other issues, the horticultural production has maintained the steady growth. Wish that in other countries also the horticulture production enhances to provide the nutritional security. Journal of Horticultural Sciences takes pride in sharing the recent research developments in different disciplines of Horticulture. Many native vegetable crops have nutraceutical values. One of them is Moringa or commonly called as drumstick. Jattan et al. have reviewed the traditional values, requirement for crop cultivation, crop improvement, value addition, nutraceutical and pharmaceutical values with respect to this crop. Many under-utilized fruit crops are brought to cultivation again with scientific interventions. One such crop is mountain sweet corn (Flacourtia montana). The fruits have high potential for processing into jam, jelly, wine, etc. and this plant has good medicinal value. Tripathi et al. evaluated and characterized the mountain sweet corn accessions from Western Ghats and identified a suitable line with higher yield, regular bearing nature and less thorniness. Ravishankar et al. isolated and characterized the microsatellite markers from the under-utilized tree species Garcinia indica. In their study, 3725 microsatellites were identified and primers were designed for 1374 microsatellites. The SSR developed will be useful in studying genetic diversity, mapping and fingerprinting of Garcinia indica and related species. Among the leafy vegetables, Amaranthus ranks first in production. Agadi et al. estimated the nature and extent of genetic variability among twenty Amaranthus genotypes. They found that Arka Arunima, Chikmagalur local, IC-551486, IC-551494 and IC-551466 recorded high foliage yield per plot and could be utilized in further breeding programme.Challam et al. studied the morpho-physiological parameters associated with resistance to iron deficiency induced chlorosis in potato and their effect on yield attributed. They found that genotype CP-3443) was found tolerant to Fe deficiency induced chlorosis. Ayub et al. evaluated responses of different okra (Abelmoschus esculentus) cultivars to water deficit conditions in Pakistan. They concluded that drought caused significant variation on physical and biochemical attributes of okra whereas the cultivar ‘Sabz Pari’ showed resistance towards the water stress. Gamma ray is an effective mutagen which creates useful variability in crops where the natural variation is very meagre and creation of variability by conventional methods is cumbersome. Lavanya et al. studied the induced variability in cluster bean due to gamma irradiation and found that the traits like iJ. Hortl. Sci. Vol. 16(1) 2021 plant height, pod length, pod width, pulp to seed ratio showed sufficient variability. Sankaran et al. also employed the gamma irradiation to generate variability in pummelo. They found that 60 Gy gamma dose can effectively be used for raising the mutant populations to identify a desirable mutation in pummelo Soil microbiome plays important role in crop production. There is need to pay attention on the nutrition management practices. They should encourage the soil microbe population that will indirectly help the plant health. Al-Mosour and Kalaivanan have demonstrated that integrated nutrient management can maximize soil microbial community dynamics which is considered as driving force behind regulating soil processes that support sustainable sweet basil cultivation. While attempting to evaluate the spectral manipulations on cultivation of cut foliage crops, Nair et al. found that coloured shade nets did not influence vase life of the cut foliage in Philodendron and observed that cultivation of Philodendron ‘Xanadu’ under white shade resulted in maximum cut foliage yield and quality. Mango ginger is an underutilized rhizomatous species that has been valued in the tropical Asian countries as a source of vegetable, spice, salad, medicine and essential oil. Huge quantity of seed rhizomes is required to promote this crop in larger area. Waman et al. developed an in vitro protocol for the multiplication of mango ginger. Jamun seed is a rich source of polyphenolic compounds with antioxidant potential and alpha - glucosidase inhibitory activity. Arivalagan et al. have optimized the methodology for the extraction of such polyphenols from jamun seeds. This will be of much in nutraceutical industry. Similarly, González et al. studied the post-harvest quality and quantification of betalains, phenolic compounds and antioxidant activity in fruits of three cultivars of prickly pear in Mexico. They observed that there was high correlation between antioxidant activity and phenolic compounds. The methodologies developed by them will be useful tool for the quantification of bioactive compounds fruit tissues. Post-harvest disease management is an important aspect in delivering the harvested produce safely to the end-user. Bhandari et al. have recorded that application of essential oils with wax improved shelf life of sweet oranges in Nepal and this treatment enhanced juice retention, firmness, titratable acidity, vitamin C and disease reduction. S. Sriram Editor in Chief J. Hortl. Sci. Vol. 16(1) 2021 ii 1 J. Hortl. Sci. Vol. 16(1) : 1-13, 2021 Review Moringa (Moringa oleifera L.) : An underutilized and traditionally valued tree holding remarkable potential Minakshi Jattan1, Kumari N.2, Raj Kumar3*, Kumar A.3, Rani B.2, Phogat D.S.1, Kumar S.1 and Kumar P.4 1Department of Genetics and Plant Breeding, CCS Haryana Agricultural University, Hisar, India 2Department of Biochemistry, CCS Haryana Agricultural University, Hisar, India 3ICAR-Centre for Soil Salinity Research Institute, Karnal, India 4Department of Plant Pathology, Punjab Agricultural University, Ludhiana, India *Corresponding author email: rajhorticulture@gmail.com ABSTRACT Moringa (Moringa oleifera L.) commonly known as “drumstick tree” belongs to the family Moringaceae. It is now grown worldwide but its native region is India. It is a fast-growing tree that responds to low inputs and has high regeneration potential after cutting. Its nutritional value and capacity to grow economically in different soils and environmental conditions makes it a wonder tree. It is highly nutritious and each part is being utilized in various forms. It is widely cultivated for its young pods, flowers and leaves for use as traditional herbal medicine and vegetable. It is also used by indigenous people in the tropics and sub-tropics as a source of remedies. The leaves are also used as a source of fodder in many countries of the world as it can sustain green fodder availability round the year without extra efforts. Various parts of this tree are good source of ascorbic acid, calcium, iron, protein and antioxidant compounds. Hence, its remarkable properties help to fight nutritional deficiency, human diseases and improve performance of livestock. Keywords: Antioxidants, Fodder, Livestock, Malnutrition, Moringa, Nutrients and Pharmaceutical INTRODUCTION Moringa (Moringa oleifera L.) also known as ben oil tree, benzolive tree, drumstick tree or horseradish tree is the most versatile and comes under the category of underutilized perennial plant species. All parts of this plant i.e. leaves, roots, flowers, pods and seeds have remarkable range of properties due to the presence of essential nutrients like vitamins, minerals, phytochemicals etc. Therefore, this plant can serve as a highly nutritious food with medicinal properties for human beings as well as fodder for livestock (Nouman et al., 2014 and Masih et al., 2019). Essential nutrients present in Moringa oleifera such as vitamins, minerals, fatty acids and amino acids are helpful in activating enzymes, hormones and osmotic adjustment in the body. Hence, enhance growth, body functions and maintenance of life processes (Anjorin et al., 2010). Also, a wide range of antioxidants available in leaves, make it a valuable source of natural antioxidants, nutraceuticals and functional components (Anwa r et al. , 2007). T her efor e, Moringa oleifera can serve as an effective remedy for malnutrition particularly in the developing countries of the world. In the present scenario when the cultivatable area for fodder production is decreasing day by day due to the cultivation of cash crops; Moringa oleifera can serve as an important source of quality fodder. This plant can be used as livestock fodder, as a supplement to enhance the dry matter intake (DMI) and digestibility of fodder in livestock. It is helpful in weight gain and enhances milk production in livestock. Fodder qua lity ca n be impr oved by mixing Moringa oleifera leaves with other fodder crops which contributes towards better livestock perfor ma nce. Hence, Moringa oleifera can be used as nutritional supplement for livestock due to its nutritional value and good biomass production (Sanchez et al., 2006). 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. 2 Jattan et al Due to several medicinal and therapeutic properties of Moringa oleifera traditionally, it has been used to treat problems such as anemia, anxiety, asthma, bronchitis, skin infections in different cultures of the wor ld. It a lso possesses a nti-dia betic, a nti- hypertensive, anti-inflammatory, anti-spasmodic and anti-tumor activities (Sharma et al., 2012). Therefore, various bioactive compounds isolated from Moringa oleifera are utilized in medicinal field at large scale (Abalaka et al., 2009). Moringa oleifera being rich in phytochemicals and nutrients as compared to vegetables; helps to enhance immunity. Hence, its consumption should be encouraged to strengthen immunity and cope up with malnutrition. The biochemical composition of different parts of Moringa oleifera varies from location to location (Anjorin et al., 2010). These variations in biochemical composition may be due to cultivation methods, environment and genetic background (Brisibe et al., 2009). There is very scanty scientific information on the potential of this species to alleviate nutritional problems. There is lack of Moringa oleifera varieties due to less infor ma tion a va ila ble on genetic improvement programs for this tree (Padulosi et al., 2013). Therefore, to solve the malnutrition problems such as protein deficiency in the population of developing countries of the world; further studies are needed on breeding and genetic improvement of this species. This information will be helpful in utilizing the full potential of this nutrient rich and incredible tree in various arenas of life. ORIGIN AND DISTRIBUTION Moringa is a member of the family Moringaceae which is comprised of thirteen species from various geographical locations (Shahzad et al., 2013). It is commercially cultivated in parts of Africa and India. Four species i.e. Moringa drouhardii (Madagascar), M. ovalifolia (Namibia and southwest Angola), M. hilderandtii (Madaga sca r) and M. stenopetala (Kenya a nd Ethiopia ) a r e cha r a cter ized by bloated water-storing trunks. Three species i.e. M. peregrine, M. oleifera and M. concanesis are known for their slender trees with juvenile stage being tuberous. The remaining six species (M. arborea, M. borziana, M. longituba, M. pygmaea, M. rivae and M. peregrina) are tuberous in nature. M. oleifera is chiefly cultivated species of Moringa genus. It is a softwood deciduous tree. It is indigenous to the Himalayan foothills. It is widely cultivated in tropical regions of South Asia from northern Pakistan to northern Bengal state in India and northeastern Bangladesh, Nepal, Afganistan, Sri Lanka, West Asia, the Caribbean and sub-Saharan Africa, Latin America and reported in Florida and the Pacific Islands (Sachan et al., 2010). TREE MORPHOLOGY Moringa oleifera tree bears spreading, open crown of drooping and fragile branches. The compound tripinnate leaves alternately bear leaflets in opposite pairs and leaf length ranges from 45-90 cm. The leaflets are dark green with red tinged midveins, entire margins and rounded at apex (Rollof et al., 2009). The soft stem wood is light weight and bark is whitish- grey, thick and corky. The deep tap root system and spreading tuberous lateral roots provide support to the tree. It may flower twice in a year or round the year. The flowers have pleasa nt smell and these a re produced in 10-25 cm long loose axillary panicles. The flower s a r e white or cea my-white in colour, zygomorphic and pentamerous (Sachan et al., 2010). Calyx contains five sepals which are green, lobed and tubular. Corolla comprises five narrowly spathelate, veined and creamy-white petals. Androecium is compr ised of five fer tile yellow sta mens with alternating five smaller sterile stamens (staminodes). Gynoecium is represented by a single, stalked superior ovary with slender style. Ovary is one celled with double rows of ovules (10-25). Moringa fruit is called as pod and looks like drumstick. Pods are large (10- 60 cm long) and turn brown at maturity. The seeds are rounded, one cm in diameter, dark brown to black in color with three papery wings. TRADITIONAL VALUE Each part of Moringa oleifera tree has immense potential (Fig 1). It was documented in Indian Vedic literature nearly 5000 years ago (Patwardhan, 2003). In the tropical and sub-tropical regions, Moringa is highly va lued by loca l people beca use of its pharmaceutical value and consumed as infusions and decoctions. This tree has served as a remedy to cure more than 300 diseases and can be regarded as a panacea. The roots have a pungent odour resembling with horseradish tree (Armoracia rusticana). It is used as a flavoring agent and in cardiac & circulatory problems (Mishra et al., 2011). Root-bark is used as antiviral, anti-inflammatory, analgesic. The leaves are J. Hortl. Sci. Vol. 16(1) : 1-13, 2021 3 Moringa : an underutilized and traditionally valued tree used as a remedial source for the treatment of various ailments like influenza, malaria, typhoid, arthritis, inflammations, skin problems, hypertension and diabetes. The flowers are generally consumed as cooked vegetable or salad. Stem-bark and flowers are hypoglycemic. Pods are antipyretic and anthelmintic. Seeds have 30-40% oil and it is called as Ben oil which is resistant to rancidity and used in cooking (Yu et al., 2005). It is also used for the treatment of hysteria, scurvy, prostate problems and bladder troubles (Fahey, 2005). Indian Ayurveda claims that Moringa oil possesses antitumor, antiepileptic, anti- inflammatory, antiulcer, antibacterial, antifungal properties and it is utilized for the treatment of different a ilments in the indigenous system of medicine. GROWTH CONDITIONS AND PLANTATION Moringa oleifera grows very fast and it can adapt to variable ecosystems and farming systems with a temperature range of 25-35 0C. It is tolerant to drought and can be grown in sandy or loamy soils. The soils which are waterlogged or poorly drained are not suitable because it may cause rotting. The soil with a slightly acidic to slightly alkaline pH is suitable for it. An annual rainfall of 250-3000 mm is essential for its proper growth. During germination phase, it can withstand up to 3 dS m–1 electrical conductivity (EC). However, its resistance to salinity increases during later stages of growth. The antioxidant system of Moringa oleifera is responsible to tolerate moderate salinity with a mild effect on its mineral composition (Nouman et al., 2012). Therefore, it can be grown in diverse environments i.e. hot, humid and dry with well drained soils. Although this plant can grow in versatile environments, yet the nutrient content and strength of the plant is ensured by the soil condition. Soil fertility, application of different doses and combinations of fertilizers; cause variations in nutrient composition of plant/plant parts (Dania et al., 2014). Moringa plantation can be done from seeds, cuttings or nursery saplings. However, direct cultivation through seeds is utilized when seed is sufficient in quantity. This method has high seed germination rate and takes 5-12 days for germination (Leone et al., 2015). It can be grown to full-sized trees to get leaves, flowers, pods and seeds as economic parts. It can also be grown as a bush and intensively planted to get leaves as the economic part (Fig. 2). The best sowing J. Hortl. Sci. Vol. 16(1) : 1-13, 2021 Fig. 1: Moringa (Moringa olefera L.) at different growth and development stages: (A) seed, (B) direct seeded sapling in field, (C) nursery raised sapling, (D) harvesting stage for fodder, (E) flowering stage, (F) fruiting stage 4 is the beginning of the rainy season. It ensures enough water to the growing tree during its first growing season to become well-established. After that, much water is not required. Planting method depends on available space and which economic part is to be subsequent cuttings. Cultivation for the pod or seed purpose requires 20 kg farmyard manure per pit at the time of sowing and then application of chemical fertilizers i.e., 100 g each of urea, super phosphate and muriate of potash per plant for getting higher yield (Kader and Shanmugavelu, 1982). The application of 7.5 kg farmyard manure and 0.37 kg ammonium sulfate per tree can increase yield up to three folds (Morton, 1991). For proper weed control weeding should be done at regular intervals whenever required. Irrigation requirement in Moringa depends on the rainfall. First irrigation should be given just after sowing. Dur ing ea r ly sta ges of development, irrigations should be managed properly for the establishment of plant. Then in later stages it should be given as per need. For the management of insect pests like hairy caterpillar; bio-pesticide like neem seed kernel extract (5 % solution) should be sprayed on the crop during infestation. POST HARVEST MANAGEMENT AND VALUE ADDITION Moringa plant parts can be used directly as a fresh harvest or these can be processed and value added through various methods for utilization in diverse forms. Lea ves and flowers are gener ally shade dried and ground to a fine powder for utilization as tea or food additive. Moringa leaf dry matter in the form of powder or pellets is also utilized as a value-added product for livestock. The roots from young plants are dried after removing root bark and powdered for use as a hot seasoning base. In ma ny countr ies, the use of Moringa a s a food fortificant is increasing rapidly. Different parts of this tree are used in making soups (Babayeju et al., 2014), weaning foods (Arise et al., 2014), herbal biscuits (Alam et al., 2014), bread (Chinma et al., 2014), cake (Kolawole et al., 2013) and yoghurt (Hekmat et al., 2015). Hence, different parts of the tree put value to diversity of food items by enhancing their nutritional potential. Also, the Ben oil obta ined from seeds after cold pressing or s olvent ex t r a c t ion ha s b een u s ed in s kin preparations and ointments since Egyptian times. The oil is used in making cosmetic products and perfumes. The oil cake is a byproduct of oil extraction and useful as an organic fertilizer. In this way, processing and value addition of Moringa leads to increase in its value and it can serve as a good source of income for small land holding farmers. J. Hortl. Sci. Vol. 16(1) : 1-13, 2021 Jattan et al Fig. 2: Potential utilities of different parts of Moringa (Moringa oleifera L.) utilized. For good seed production, 2-3 seeds per hole are planted 2-3 cm deep with 2-5 meter spacing between trees depending of the annual or perennial types. For good leaf production, dense planting should be done i.e., 30 cm x 10 cm spacing. When the trees reach about 1.5 m tall, prune them down to 15 cm. The pruned rows grow back with a greater number of branches and leaves. It gives a continuous supply of leaves. Plantation can be done from cuttings having diameter 4-5 cm and length 100 cm; by digging a hole, adding manure and mounding the soil (Peter, 1978). The sprouting takes variable time depending on various factors like genotype, length of cuttings and growth conditions. However, plants grown from cuttings are sensitive to winds and drought due to lack of strong root system. It can also be cultivated through nursery raised saplings. The saplings are grown in plastic bags having sandy or loamy soils. Saplings have tender roots and hence transplanted carefully when attain the height of about 30 cm. AGRONOMIC MANAGEMENT Field preparation for cultivation is done by adding farmyard manure (10 MT/ha) and chemical fertilizers. The application of chemical fertilizers depends on the soil condition. Generally, Moringa oleifera cultivation for fodder purpose needs 150 kg nitrogen, 60 kg phosphorus, 40 kg potash, 30 kg sulphur and 10 kg zinc sulphate for one hectare. Nitrogen is given in split doses; 30 kg at the time of filed preparation and later equal split doses i.e. after 45 days of sowing and after seed oil leaves seeds pods flowers HUMAN FOOD USES ANIMAL FEED & FODDER PHARMACEUTICAL pods leaves seed oil roots gumtwigs leaves branches 5 NUTRITIONAL POTENTIAL OF MORINGA Moringa oleifera is used to fight malnutrition among infants and nursing mothers especially promising in the tropics because it can provide leaves as a source of food and fodder even in dry period when other sources are typically scanty (Folkard and Sutherland, 1996). Moringa has enormous potential as it is helpful in improving human health, weight gain and milk production in livestock. As a food sensere care There should be sustainability and stability in quality food supply for raising any stable community. Cereals, pulses, vegetables, fruits, meat and milk are the sour ces of food which fulfill our nutr itiona l requirements. However, many of these food items are not affordable by a large population, especially those living below the poverty line. In developing countries, the diet is devoid of proteins, vitamins and minerals. Therefore, for these people; plants that are particularly nutritious represent a valuable option to fulfill such needs. Moringa oleifera has the potential to fulfill ma ny of such needs Due to the multitudes of properties which are harbored by this tree species. Mor inga lea ves ha ve plentiful of nutr itiona l components. The leaves can be taken fresh, cooked or in the form of dry powder. The dry powder retains its nutr itiona l value for ma ny months without refrigeration. The leaves and pods are generally used in common food items. Moringa leaves are rich in vitamin A, C and E (Hekmat et al., 2015). Dry leaves contain ten times more vitamin A than carrot and seven times more vitamin C than orange. Minerals i.e., iron (25 times than spinach), potassium (15 times than bananas) and calcium (17 times than milk) are also in abundance in dry powder of Moringa (Rockwood et al., 2013). Moringa leaves also contain large amount of magnesium, manganese, copper, zinc and iron (Hekmat et al., 2015). Moringa leaves are rich in protein and this is cited in various studies (Thurber and Fahey, 2009). The studies also reveal that average crude protein in animal milk is much less in comparison to fresh and dry moringa leaves (Stelwagen, 2003; Chandan, 2006). Moringa leaves possess higher amino acids content than those recommended by Food and Agriculture Organization (Mendieta-Araica et al., 2011). Moringa seed meal contains large number of amino acids, except for valine, lysine, and threonine (Oliveira et al., 1999). Moringa dry leaves and fresh pods contain higher contents of arginine, valine and leucine. However, some amino acids (serine, glutamate, aspartate, proline, glycine and alanine) have not been identified in dry leaves and fresh pods (Fuglie, 2000). The phytonutrients (carotenoids, tocopherols and ascorbic acid) have also been reported in Moringa leaves which help in free radical scavenging (Dan Malam et al., 2001; Saini et al., 2014a; Saini et al., 2014b). Moringa flowers and pods also contain appreciable amounts of carotenoids. Therefore, moringa is the best food supplement for children and infants to combat malnutrition. The whole seeds of moringa can be eaten as such, roasted or used in powdered form. Moringa seeds have sweet to bitter taste and are consumed mostly after frying (Makkar and Becker, 1996). Moringa seed oil (Ben oil) is used for cooking and salad dressing. Ben oil in seeds is about 30-40% which is rich in unsaturated fatty acids (82%) (Ferrao and Mendez, 1970). The fatty acids present in oil are; linolenic acid, linoleic acid, oleic acid, palmitic, stearic, and behenic acid. The seeds also contain fibre, minerals, proteins, vitamins and amino acids (Kasolo et al., 2010). As animal feed and fodder Various tree species are utilized as a fodder for lives t oc k o r s u p p lement low qu a lit y f odder especially in the dry period (Otsyina and Dzowela, 1995). M. oleifera has the potential to supplement low-quality livestock fodders thereby increasing dry matter intake (DMI) and digestibility. It serves as the best example of quality fodder for increasing milk and meat production along with its environment friendly nature and low input requirements. The gr een f odd er a s well a s dr y ma t t er ( D M ) production depends on the fertilizer, genetic make- up, season and ecological conditions (Palada et al., 2 0 07 ) . M a c r onu tr ient s whic h a r e p r es ent in abundance in Moringa play important roles like tissue building, physiologica l, meta bolic, a nd biochemical processes in livestock. Magnesium (Mg) and Potassium (K) are important for lactating animals. The lactating cows require 0.17–0.20% Mg in dry matter (NRC, 1996). Magnesium (Mg) deficiency during lactating period results in low blood Mg which causes low milk yield. Similarly, beef cows require 0.70% K in dry matter. Besides essential nutrients a nd multivitamins, Moringa leaves also possess crude protein (21.8%), acid J. Hortl. Sci. Vol. 16(1) : 1-13, 2021 Moringa : an underutilized and traditionally valued tree 6 detergent fibre (22.8%), and neutral detergent fibre ( 3 0 . 8 % ) . T he c r u de f a t ( 4 1 2 . 0 g kg – 1) , carbohydrates (211.2 g kg–1) and ash (44.3 g kg– 1) ha ve a lso been r epor ted in Mor inga lea ves (Oliveira et al., 1999). All these compounds are important in increasing livestock production. Hence, Mor inga leaves which are rich source of these nutrients; fulfill the nutritional requirements of livestock in the best possible way. Different plant parts (leaves, twigs or branches etc.) of this tree have variable concentration of nutrients. Hence, the fodder mixtures containing different proportions of Moringa plant parts provide an array of nutrition. For example, mixing of Moringa leaves with soft twigs in fodder provides lower CP and higher NDF contents, whereas mixing Moringa leaves with seed cake in fodder provides higher CP contents (Murro et al., 2003 and Fujihara et al., 2005). Depending upon the nutritional requirement of an animal; specific combination of Moringa plant parts can be given to the animal so that it can utilize the fodder in a best way. As for an example, moringa leaves with twigs having low crude protein can be given to dry cows, requiring low nutrient fodders. Animals like cattle, goat, sheep, rabbits as well as pigs easily eat green leaves and stems of Moringa (Mulugeta and Fekadu, 2014). It incr eases the animal weight gain and protein intake (Aharwal, 2 01 8 ). Pos it ive ef f ec ts of dif fer ent p a r t s of M or inga ha ve b een r ep or t ed in t he f or m of increased milk yield in cows, growth rate in sheep a nd feeding beha vior in goa t. Livestoc k feed supplemented with Moringa leaves can increase up to 32% of daily weight gain in livestock. Mixing of fresh Moringa leaves (15 to 17 kg) in daily feed of livestock can boost milk production by 43%. The milk production can be increased further with the supplementation of dry matter feed i.e., 58 and 65% increase by 2 kg and 3 kg dry matter feed, respectively (Foidl et al., 2001). Moringa diet has t he highes t eff icienc y of pr otein & nit r ogen utilization and nutrient digestibility (Sultana et al., 2015). Moringa Leaf Meal (MLM) can also be included in poultry and fish meal. The MLM in poultry feed can be particularly used by the small farm holders as natural and healthy feed substitute to synthetic feed supplements (Hermogenes et al., 2014). Moringa leaves which are rich in protein help in improving the microbial protein synthesis in rumen of animals. Hence, it is a suitable alternate of soybean and rapeseed meal and can be given to ruminants (Soliva et al., 2005). Anti-nutritional factors Besides nutritional factors, antinutritional factors are also reported in many food and fodder trees a nd these exert negative effect on human and a nima l hea l t h b y int er f er ing wi t h va r iou s physiological processes. Therefore, such trees are not selected as priority for food and fodder. Some trees belonging to genus Acacia, Albizia, Sesbania are utilized for fodder purpose and these possess antinutritional factors (Kumar, 1992). However, Moringa oleifera represents unique property of being rich in minerals and lower in antinutritional factors. Moringa leaves possess tannins that range from 13-20 g kg-1of dry leaves and it is very less in c omp a r is on t o S e s b a n i a s e s b a n , A c a c i a angustissima, and Acacia cyanophylla leaves (31, 66 and 38 g kg–1, respectively). The concentration of phytates is also low in Moringa and it ranges from 25-31 g kg-1of the dry leaves (Ahn et al., 1989; Makkar and Becker, 1996; Salem et al., 1999). Lectins, trypsin, and amylase inhibitors have not been reported in Moringa leaves (Ferreira et al., 2008). The glucosinolates and isothiocyanates have been reported in Moringa leaves and roots (Bennet t et a l. , 2 003; Newton et a l. , 2 010 ). However, their concentration depends upon the soil type, climatic conditions, cultivar and its growth stage. Moringa leaves possess saponins, which impart a bitter taste. Saponins and isothiocyanates do not always have harmful effects and hence can be consumed by both livestock and human beings ( F oidl e t a l . , 2 0 0 1 ; P r ic e, 2 0 0 0 ) . O t her antinutritional factors found in many fodder trees a r e oxa la t es . H owever, ox a la t es r ep or t ed in Moringa leaves are mainly insoluble oxalates and hence do not cause harmful effect (Radek a nd Savage, 2008). Hence, Moringa oleifera is having better nutritional composition tha n other lea fy vegetables or fodders and can be utilized for food as well as fodder purpose. PHARMACEUTICAL POTENTIAL OF MORINGA The various parts of Moringa oleifera possess antioxidative, anti-inflammatory, antitumor, antiulcer, antibacterial and antifungal properties. Many bioactive J. Hortl. Sci. Vol. 16(1) : 1-13, 2021 Jattan et al 7 compounds like glycosides, malonates and flavonoids have been isolated from Moringa oleifera (Bennett et al. , 2003; Miea n a nd Moha med, 2001). Isothiocyanates isolated from Moringa leaves possess the capability to fight against human tumor cells. The reason behind this activity may be its capability to induce reactive oxygen species in cancerous cells which is target specific (Tiloke et al., 2013; Jung, 2014; Leelawat and Leelawat, 2014). Many of the plant glycosides can be used in treatment of cancer or chronic diseases (Chumark et al., 2008; Ghasi et al., 2000; Murakami et al., 1998). Lipid peroxidation plays an important part in artherogenesis, thrombosis and cancer development. The flavonoids isolated from Moringa leaves could modulate this process of lipid peroxida tion and hence ca n combat with these diseases. The flavonoids also help in scavenging of free radicals and inhibition of oxidative and hydrolytic enzymes which ar e involved in sever al chr onic diseases (Rodrigo et al., 2011; Siddhuraju and Becker, 2003). Quercetin, which is a powerful antioxidant, also helps in lowering blood pressure (Larson et al., 2012). Moringa leaf powder also helps in reducing blood sugar levels due to the presence of isothiocyanates (Kushwaha et al., 2014; Waterman et al., 2015). Moringa leaf, pod and seeds also possess anti- inflammatory properties (Cheenpracha et al., 2010). However, these results are based on lab and animal studies and confirmation on human beings further needs to be verified. Pods are helpful in treating eye disorders, diarrhea, joint pain, liver and spleen problems. T he immature pods are used against intestinal worms (Kasolo et al., 2010). Moringa seeds help in treating many diseases like epilepsy, arthritis, viral diseases etc (Kasolo et al., 2010 and Sutalangka et al., 2013) . The flowers of Moringa can cure arthritis, cold, urinary and heart problems (Fuglie, 2005). The gum is used as an antiseptic (Rajangam et al., 2001). The fresh root is used in case of intermittent fever. It can also be applied externally as a paste to treat inflammation, palsy, dropsy and animal bites. The root infusion helps in treating asthma and a scites. Root ba rk acts as a n a nti-ulcer, anti- inflammatory and cardiac stimulatory agent (Mishra et al., 2011 and Fahey, 2005). CROP IMPROVEMENT M o r i n g a o l e i f e r a is a c r os s - p ollina t ed t r ee species having diploid chromosome number equal t o 2 8 . T he r ef or e, high het er o geneit y in morphological, physiological and quantitative traits is anticipated. This tree presents diversity of forms i. e . , a nnu a l to per ennia l typ es, deciduous to evergreen, semi-spreading to upright. Also, some trees flower in two sea sons a nd others flower throughout the year (Raja et al., 2013). Hence, the variability present in various characters can be a source for genetic improvement. However, lack of elite cultivars adapted to local environment and use of open pollinated seed for crop cultivation may be impor t a nt f a ct or s tha t limit its pr oduct ivit y. Moreover, the number of germplasm accessions and active germplasm banks are incipient across the world. Despite India, some other research centres like AVDRC (Taiwan), Rural development initiative (Za mbia ) a nd Mor inga Philippines founda tion (Philippines); are also involved at the global level, in mor inga impr ovement. Ma ny ecotypes viz. Jaffna, Chavakacheri murungai, Chemmurungai, Kadumurungai and Kodikkal murungai have been reported in India (Kumar et al., 2014). Despite huge variability in Moringa oleifera no institution has database for cultivated or natural germplasm accessions. There is great inconsistency between the inherent genetic variability in this species and reflected in available germplasm. Hence, priority must be focused on the fixation of poor variability in a va ila b le ger mp la s m in ger mp la sm ba nks because it may hinder with the progress of crop improvement programs. Any crop improvement program depends on the available genetic diversity. There is much less information available on genetic diversity of genus Moringa. Some of the studies show a wide genetic diversity present in Moringa (Ramachandran et al., 1980; Shahzad et al., 2013; Suthanthirapandian et al., 1989). These studies also emphasize on the great potential for genetic improvement of this species to enhance the use of this under-utilized t r ee. T her e is one downs ide a ls o i. e. , s ome antinutritional factors in Moringa can reduce the absorption of minerals and protein (Richter et al., 2003; Teixeir a et al., 2014). Hence, differ ent st r a tegies shou ld be exp lor ed t o ha r ness t he available genetic diversity. The true understanding of genet ic diver s it y c a n b e ga i ned b y t he cha racteriza tion of both cultivated and natural accessions present all over the wor ld. Var ious J. Hortl. Sci. Vol. 16(1) : 1-13, 2021 Moringa : an underutilized and traditionally valued tree 8 breeding programs, including plant introduction, evaluation, selection, hybr idiza tion a nd use of biotechnological methods have been employed for the development of varieties with dwarf stature, high biomass production, high seed yield and oil content, better quality, resistance to pest and diseases. Introduction T he va r iety, Ja ffna is pr esumed to ha ve been introduced from Sri Lanka. It is cultivated in Southern India. Chavakacheri murungai is also an introduced variety from Sri Lanka. Selection (Mass and Pure line) The selection of plants starts with open pollination. The plants are selected based on production potential and tested under various conditions and sites. Then, it is followed by controlled pollination. The variety, PKM 1, has been developed through pure line selection. It is annual type and best suited for tropical plains. Hybridization and selection It involves hybridization between diverse genotypes followed by selection. The variety, PKM 2 is derived from a cross involving MP31 and MP28 as parents. It is annual type and gives 48% more yield over PKM1. It is suitable for cultivation in tropical plains of India. Mutation breeding It is also an important breeding method for creation of variability or novel traits. However, this method is not much utilized in Moringa. Molecular breeding Work on Mor inga crop improvement ba sed on biotechnology or molecular breeding is very limited and it is just at budding stage. It is obvious from the nucleotide da tabase (NCBI) which possess very less sequence information (DNA and RNA). Recently, due importance has been given to micro propagation (Kantharajah and Dodd, 1991) and use of molecu la r ma r ker s for cha r a cter iza tion of germplasm for crop improvement. Use of molecular markers can enhance the genetic improvement as it helps in identifying diverse genotypes. These diverse genotypes can be utilized in hybridization pr ogr a ms to pr oduce r ecombina nts with wide variability. Biotechnological studies in Moringa started with the use of dominant markers. The amplified fragment length polymorphism (AFLP) marker technique was used to study diversity in natural populations from India and introduced populations in Malawi and Kenya (Muluvi et al., 1999). In this study it was noticed that the population differentiation was significant and genotypes separated according to geographical origin. Further, randomly amplified polymorphic DNA (RAPD) marker technique was used by different researchers to study diversity among cultivated and non-cultivated population of Moringa (Mgendi et al., 2010; Abubakar et al., 2011; Da Silva et al., 2012; Saini et al., 2013 and R u fa i e t al . , 2 0 1 3 ) . I n a ll t hes e s t u dies a n appreciable level of genetic diversity was reported in natural populations with respect to cultivated ones. Hence, less genetic diversity in cultivated a cc ess ions indic a t es t ha t ther e is a n ut mos t requirement to widen the genetic base for crop improvement programs. Later, with the advent of co-dominant markers like simple sequence repeats (SSRs), the molecular genetic diversity studies got impr oved. Mor inga a ccessions collected fr om different countr ies (Pa kista n, India, Ta nzania , Senegal, Mozambique, Zimbabwe, Florida, Mexico, Haiti and Belize) have been evaluated earlier and it has been reported that there was high genetic diversity in wild Pakistan accessions, as compared with other accessions (Shahzad et al., 2013). Both morphological and molecular markers (SSRs) have been used for characterization of 300 genotypes of Moringa collected from different locations of India and large diversity have been observed (Ganesan et al., 2014). Both these markers have been used later to screen 34 genotypes of Moringa collected from different regions of Tamil Nadu (Natarajan and Joshi, 2015). It has resulted in identification of s up er ior genot yp es which c a n b e ut iliz ed in hybridization program to improve oil yield. In this way, morphological markers along with molecular markers can prove an authentic tool to enhance and strengthen breeding programs of Moringa. CONCLUSIONS AND FUTURE PERSPECTIVES Moringa oleifera has several strengths and potential utilities. The usage and merits of Moringa as food, livestock fodder and pharmaceutica l have been documented widely. Although Moringa plant has J. Hortl. Sci. Vol. 16(1) : 1-13, 2021 Jattan et al 9 Babayeju, A., Gbadebo, C., Obalowu, M., Otunola, G., Nmom, I., Kayode, R., Toye, A. and Ojo, F. 2014. Comparison of organoleptic properties of egusi and eforiro soup blends produced with Moringa and spinach leaves. Food Sci. and Qual. Manage., 28: 15-18. Bennett, R. N., Mellon, F. A., Foidl, N., Pratt, J. H., DuPont, M. S. and Perkins L. 2003. Profiling glucosinolates and phenolics in vegetative and reproductive tissues of the multi-purpose trees Moringa oleifera L. (Horseradish tree) and Moringa stenopetala. J Agric Food Chem, 51: 3546-3553. Brisibe, E. A., Umoren, U. E., Brisibe, F., Magalhaes, P. M., Ferreira, J. F. S., Luthria, D., Wu, X. and Prior, R. L. 2009. 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