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Cactus Pear: a Weed of Dry-Lands for Supplementing Food Security Under Changing Climate

Pera de Cacto: Uma Planta Daninha de Terras Secas para Suplementação de Segurança Alimentar sob Mudança Climática

ABSTRACT:

Climate change characterized by global warming and frequent occurrence of prolonged drought spells has necessitated the cultivation of multi-purpose crops which are temperature and drought hardy. This paper evaluates the production potential of cactus pear [Opuntia ficus indica (L.) Mill.] as an alternate and low-cost forage crop along with the recent advancements in its cultivation and utilization as food crop for supplementing the food security of rapidly increasing populace. The botanical, ecological and physiological traits enabling cactus pear to survive under harsh agro-climatic conditions have been objectively elaborated. A variety of impediments hampering its wide-scale cultivation and future breeding needs for improving the biomass production and nutritional quality have also been identified. The potential of cactus pear to reduce desertification along with imparting sustainability to modern, commercial and profitable agriculture in dry-lands makes it an exceptional plant. Its annual biomass (stems called cladodes) yield of 40-50 t ha-1 with an appropriate agronomic management may sustain 5-6 adult cows supporting a family of 12-16 people. However, its slow growth, less fruit yield, poor nutritional quality of forage and the fear of cactus pear becoming a noxious weed restricts its popularized cultivation and thus demands a comprehensive genetic improvement and agronomic technology package.

Keywords:
Opuntia ficus indica; cladodes; emergency water supply; forage bank; Indian fig

RESUMO:

As mudanças climáticas caracterizadas pelo aquecimento global e frequente ocorrência de períodos prolongados de seca têm demandado o cultivo de culturas multiúsos, que são resistentes à temperatura e à seca. Neste artigo é avaliado o potencial de produção de pera de cacto [Opuntia ficus indica (L.) Mill.] como uma cultura de forragem alternativa e de baixo custo, juntamente com os recentes avanços em seu cultivo e utilização como cultura de alimentos para complementação da segurança alimentar de uma população em rápido crescimento. As características botânicas, ecológicas e fisiológicas que permitem que a pera de cactos sobreviva sob condições agroclimáticas adversas, têm sido objetivamente elaboradas. Uma variedade de impedimentos que dificultam o cultivo em larga escala e as futuras necessidades de melhoramento da produção de biomassa e da qualidade nutricional também foram identificadas. O potencial da pera de cacto para reduzir a desertificação, juntamente com a sustentabilidade para a agricultura moderna, comercial e rentável em terras secas torna uma planta excepcional. Seu rendimento de biomassa anual (caules chamados cladódios) de 40-50 t ha-1 com manejo agronômico adequado pode sustentar 5-6 vacas adultas alimentando uma família de 12-16 pessoas. Entretanto, o crescimento lento, o menor rendimento da fruta, a qualidade nutritiva pobre da forragem e o medo de a pera do cacto tornar-se uma planta daninha nociva restringem seu cultivo popularizado, exigindo assim um melhoramento genético abrangente e um pacote de tecnologia agronômica.

Palavras-chave:
Opuntia ficus indica; cladódios; abastecimento de água de emergência; banco de forragem; figo indiano

INTRODUCTION

Under changing climate, sustainable productivity of dry-lands (arid and semi-arid) depends on the cultivation of drought resistant crops and development of sustainable cropping systems (Santini and Carlos, 2013Santini BA, Carlos M. Does retained-seed priming drive the evolution of serotiny in drylands? An assessment using the cactus Mammillaria hernandezii. Am J Bot. 2013;100:365-73.). Dry-lands cover 40% of the global area and sustain more than 2 billion inhabitants, characterized with precipitation to evapotranspiration ratio of 0.05-0.65 (Grunwaldt et al., 2015Grunwaldt JM, Guevara JC, Grünwaldt EG. Review of scientific and technical bibliography on the use of Opuntia spp. as forage and its animal validation. J PACD. 2015;17:13-32. ). Climate change induced rising temperatures along with frequent and prolonged drought spells have further aggravated the problems of arid regions due to shallow soils with low water storage capacity (Bariagabre et al., 2016Bariagabre SA, Asante IA, Gordon C, Ananng TY. Cactus pear (Opuntia ficus indica L.): A future asset for sustainability of drylands in Northern Ethiopia. Int J Sci Environ Technol. 2016;5(3):846-60. ). Thal, Thar, Cholistan and Kharan in Pakistan are characterized with increased duration, intensity and frequency of drought that cause shortage or even absence of water, food and feed leading to malnutrition, hunger and even death (Diniz et al., 2017Diniz WJS, Silva TGF, Ferreira JMS, Santos DC, Moura MSB, Araújo GGL, et al. Forage cactus-sorghum intercropping at different irrigation water depths in the Brazilian Semiarid Region. Pesq Agropec Bras. 2017;52(9):724-33. ). Food security of rapidly increasing human population in these regions is compromised owing to shortage of forages which result in low productivity of ruminants. This situation requires cultivation of crops that have moderate to high carrying capacity, high potential for rapid utilization and quick recovery after severe consumption. In addition, crops must have drought tolerance, rapid establishment, minimum production costs, high tolerance against soil toxicities and erratic weather conditions along with being safe for ruminant health (Neffar et al., 2013Neffar S, Chenchouni H, Beddiar A, Redjel N. Rehabilitation of degraded rangeland in drylands by Prickly pear (Opuntia ficus indica L.) plantations: Effect on soil and spontaneous vegetation. Ecol Balk. 2013;5(2):63-76.).

Cactus pear [Opuntia ficus indica (L.) Mill.] is also known as Indian fig, Barbary fig and prickly pear (Volpe et al., 2018Volpe M, Goldfarb JL, Fiori L. Hydrothermal carbonization of Opuntia ficus indica cladodes: Role of process parameters on hydrochar properties. Biores Technol. 2018;247:310-8.). It is not only able to tolerate drought (Diniz et al., 2017Diniz WJS, Silva TGF, Ferreira JMS, Santos DC, Moura MSB, Araújo GGL, et al. Forage cactus-sorghum intercropping at different irrigation water depths in the Brazilian Semiarid Region. Pesq Agropec Bras. 2017;52(9):724-33. ), but also greater biomass accumulator. Its resource conversion ability is five times greater than C3 grasses and three times higher than C4 broadleaf crops owing to Crassulacean acid metabolism (CAM) (Abidi et al., 2013Abidi S, Salem H, Nefzaoui A, Vasta V, Priolo A. Silage composed of Opuntia ficus indica f. inermis cladodes, olive cake and wheat bran as alternative feed for barbarine lamb. Acta Hortic. 2013;995:297-302.; Cano et al., 2017Cano MP, Gómez-Maqueo A, García-Cayuela T, Welti-Chanes J. Characterization of carotenoid profile of Spanish Sanguinos and Verdal prickly pear (Opuntia ficus indica, spp.) tissues. Food Biochem. 2017;237:612-22.). Its high potential to grow on severely eroded soils where other crops fail to germinate makes it suitable to be grown as food and forage crop in deserts (Lucivania et al., 2018Lucivania RL, Silva TGF, Jardim AMRF, Souza CAA, Queiroz MG, Tabosa JN. Growth, water use and efficiency of forage cactus-sorghum intercropping under different water depths. Rev Bras Eng Agríc Amb. 2018;22:113-8.). It is widely distributed across the arid areas of Brazil (0.60 Mha), Mexico (0.23 Mha), Algeria (0.15 Mha), Tunisia (0.61 Mha), South Africa (0.53 Mha) and on a smaller scale in Argentina (Grunwaldt et al., 2015Grunwaldt JM, Guevara JC, Grünwaldt EG. Review of scientific and technical bibliography on the use of Opuntia spp. as forage and its animal validation. J PACD. 2015;17:13-32. ).

Cactus pear may be grown as a strategic crop for combating desertification by reducing or partially controlling the soil erosion through its extensive root system (Maurizio et al., 2018). Its wide-scale cultivation offers protection to local fauna due to its ability to grow and reproduce in scarce rainfall and high temperatures (Ramos et al., 2013Ramos AO, Ferreira MA, Véras ASC, Costa SBM, Conceição MG, Silva EC, et al. Different fiber sources in diets based on spineless cactus in sheep feeding. Rev Bras Saude Prod Anim. 2013;14:1-12.; Ciriminna et al., 2017Ciriminna R, Delisi R, Albanese L Meneguzzo F, Pagliaro M. Opuntia ficus indica seed oil: Biorefinery and bioeconomy aspects. Eur J Lipid Sci Technol. 2017;119(8). doi:10.1002/ejlt.201700013 ). It remained superior under arid environment for providing the digestible energy, carbohydrates, abundant water, minerals and numerous vitamins (Ben-Salem and Ennouri, 2013Ben-Salem H, Ennouri K. Nutritive value and palatability of cladodes of spiny cactus (Opuntia amyclae) or spineless cactus (Opuntia ficus indica f. inermis) measured on adapted and non-adapted goats. Acta Hortic. 2013;995:325-30.; Nefzaoui et al., 2014Nefzaoui A, Louhaichi M, Ben Salem H. Cactus as a tool to mitigate drought and to combat desertification. J Arid Land Stud. 2014;13:121-4.). Cactus pear is marginally utilized as forage, food, beverages, and medicine, dyeing clothes and for various religious practices (Silva et al., 2016Silva NGM, Santos MVF, Dubeux Júnior JCB, Cunha MV, Lira MA, Ferraz I. Effects of planting density and organic fertilization doses on productive efficiency of cactus pear. Rev Caatinga. 2016;29(4):976-83.). However, it continues to remain an underutilized natural resource despite huge potential to supply abundant amounts of forage to large ruminants, triggering economic activities in sandy areas while contributing to food security of millions across the arid areas.

Although, there have been numerous studies for determining the nutritional quality of cactus pear but as per our knowledge, there has been no systematic review study focusing on agronomic technology package of spineless cactus pear and future breeding needs to promote its cultivation in arid regions. The objective of this review study is to systematically analyze the botanical and eco-physiological traits of cactus pear which enable it to thrive under severe and prolonged spells of drought and high temperatures. In addition, the potential of spineless cactus pear to serve as a food for human, forage and an emergency source of moisture for ruminants was also assessed. An appropriate agronomic management plan was evaluated for obtaining the maximum biomass of cactus pear under varying agro-climatic conditions along with the future breeding needs for utilizing it to supplement the food security of people living in dry-lands.

BOTANY OF CACTUS PEAR

Cactus pear belongs to division Magnoliophyta and class Magnoliopsida, while its order and family are Caryophyllales and Cactaceae respectively. Genus Opuntia has around 300 species, of which 104 are of Mexican origin, while the number of its sub-genera reaches to eleven (Scheinvar, 1995Scheinvar L. Agro-ecology cultivation and uses of cactus pear. Plant production and protection paper (FAO). no. 132. 1995.). There are four cultivated species of cactus including O. albicarpa, O. ficus indica, O. robusta and O. cochenillifera. Opuntia ficus-indica (cactus pear) is the most common and widely known genus of Opuntia (Majure et al., 2017Majure LC, Judd WS, Soltis PS, Soltis DE. Taxonomic revision of the Opuntia humifusa complex (Opuntieae: Cactaceae) of the eastern United States. Phyton. 2017;290:1-65. ).

It is an angiosperm and dicotyledonous plant which has developed a number of physiological, anatomical and phonological adaptations that make it more suited to grow efficiently in arid areas. Mechanism of asynchronous reproduction characterized by ability to continue reproductive stage over a longer period of time combined with the trait of succulence and crassulacean acid metabolism (CAM) have enabled it to survive prolonged spells of drought for years (Lima et al., 2016Lima GFC, Rego MMT, Dantas FDG, Lôbo RNB, Silva JGM, Aguiar EM. Morphological characteristics and forage productivity of irrigated cactus pear under different cutting intensities. Rev Caatinga. 2016;29(2):481-8.). Its stems are called cladodes while its fruit (red, orange, yellow or purple colour) is referred to as nochtli. Cactus pear is perennial shrub and may grow up to the height of 20 meters (Reis et al., 2014Reis CMG, Ribeiro MM, Gazarini LC. Biometric characterization and evaluation of portuguese populations of Opuntia ficus indica (L.) Mill. Agroforum. 2014;33:7-17. ). The root system of cactus pear is horizontal which rarely penetrates deep into the soil and mostly remains 30 cm below the soil (Tiznado-Hernández et al., 2010Tiznado-Hernández ME, Fortiz-Hernández J, Ojeda-Contreras AJ, Rodriguez-Felix A. Use of the elliptical mathematical formula to estimate the surface area of cladodes in four varieties of Opuntia ficus indica. J PACD. 2010;12:98-109. ). In cross-sectional view, the outer layer of root is epidermis having single cell layer with very few root hair. In the core of root, there is cortex made of multilayers of cells with abundant intercellular spaces through which CO2 and O2 movement occurs by diffusion (Yang et al., 2015Yang L, Lu M, Carl S, Mayer JA, Cushman JC, Tian E, et al. Biomass characterization of Agave and Opuntia as potential biofuel feedstocks. Biomass Bioenergy. 2015;76:43-53.). Whenever there is rainfall, numerous roots are developed from shallow roots of cactus pear called as rain roots, which assist in making cactus pear more hydrated than the soil. Its stem is oblong shaped having a thick waxy layer of epidermis which prevents water loss by solar radiation (Soni et al., 2015Soni ML, Soni M, Yadava N. Evaluation for growth and yield performance of prickly pear cactus (Opuntia ficus indica (L.) Mill) accessions in hot arid region of Bikaner, India. Range Manage Agrof. 2015;36:19-25.).

The cladodes (stems) of cactus pear are also called as pads or paddles and contain about 90% water and 10% dry matter. These are the photo-synthetically active organs where photo-synthates are produced, stored and trans-located to plant sinks. Cladodes or pads can be flat (platyopuntias having more than 120 species) or cylindrical (cylindropuntias having around 40 species); however flattened pads have been reported to harness more light energy than cylindrical cladodes (Ervin, 2012Ervin GN. Indian fig cactus (Opuntia ficus indica (L.) Miller) in the Americas: an uncertain history. Haseltonia. 2012;17:70-81.; Gebresamuel and Gebre-Mariam, 2012Gebresamuel N, Gebre-Mariam T. Comparative physico-chemical characterization of the mucilages of two cactus pears (Opuntia sp.) obtained from mekelle, northern Ethiopia. J Biol Nonobiotechnol. 2012;3:79-86. ). On cladodes, a bud like structure (areole) is present which has meristematic cells and give rise to new cladodes that are referred to as glochids. These are very loosely bonded to cladodes and may detach on a gentle touch. Leaves are produced by young cladodes and are ephemeral with little photosynthesis (Isaac, 2016Isaac AA. Overview of Cactus (Opuntia ficus indica (L): A myriad of alternatives. Ethno Med. 2016;12:195-205.). Leaves of cactus pear develop into specialized spines while these are mistakenly understood as leaves that are actually stems (Gebresamuel and Gebre-Mariam, 2012). Cactus pear fruit is classified as false fruit as it is comprised of floral tube which contains ovary within it. There is large number of hard seeds dispersed within the pulp of fruit (Padrón et al., 2011Padrón B, Nogales M, Traveset A, Vilà M, Martínez-Abraín A, Padilla DP, Marrero P. Integration of invasive Opuntia spp. by native and alien seed dispersers in the Mediterranean area and the Canary Islands. Biol Invasion. 2011;13(4):831-44.; Robertson et al., 2011Robertson MP, Harris KR, Coetzee JA, Foxcroft LC, Dippenaar-Schoeman A, Van Rensburg B. Assessing local scale impacts of Opuntia stricta (Cactaceae) invasion on beetle and spider diversity in Kruger National Park, South Africa. Afr Zool. 2011;46:205-23.).

ECO-PHYSIOLOGY

Crassulacean acid metabolism (CAM) for gaseous exchange and nocturnal stomatal opening at the coolest time of the day may be constituted as the physiological bases of ecological success of cactus pear in harsh climates (Lee, 2010Lee JS. Stomatal opening mechanism of CAM plants. J Plant Biol. 2010;53:19-23.). Under moderate temperatures and wet conditions, CO2 uptake starts at late afternoon and maximized few hours after dusk. A sharp rise in CO2 uptake occurs at dawn when light facilitates the incorporation of CO2 into carbohydrates (Sharafi et al., 2012Sharafi S, Ghasemi S, Jouyban Z, Akhlaghi S. Effect of water stress on agronomic traits of cactus pear (Opuntia ficus indica L.). Life Sci J. 2012;9:83-7.). The up-taken CO2 in CAM plants is bonded to 3-C compounds to form 4-C organic acids like malate (Liguori et al., 2013Liguori G, Inglese G, Pernice F, Sortino G, Inglese P. CO2 uptake of Opuntia ficus indica (L.) Mill. whole trees and single cladodes, in relation to plant water status and cladode age. Italian J Agron. 2013;8:14-20.; Torres-Ponce et al., 2015Torres-Ponce RL, Morales-Corral D, Ballinas-Casarrubias ML, Nevarez-Moorillon GV. Nopal: semi-desert plant with applications in pharmaceuticals, food and animal nutrition. Rev Mex Cienc Agric. 2015;6(5):1129-42.). Overnight, the organic acids are stored in large vacuoles and subsequent release of CO2 from the stored organic acids causes decrease in the acidity of tissues during the day. This trapped CO2 owing to closure of stomata during the day is the only that gets incorporated into photosynthetic products in the chlorenchyma tissues (Liguori et al., 2014). The water use efficiency (ratio of CO2 fixed in photosynthesis to water lost through transpiration) of cacti was recorded to be 0.022 (1.14 mol m-2 day-1 CO2 fixed at the loss of 51 mol m-2 day-1) which was triple than maize and sugarcane, while 5-fold higher than wheat, rice, cotton, alfalfa etc. (Saenz, 2013Saenz C. Opuntias as a natural resource. In: Sáenz C, editor. Agro-industrial utilization of cactus pear. Rome: FAO; 2013. p.17-21.). Insects have been reported to be efficient pollinating agents for cactus pear besides birds and bats on a smaller extent (Padrón et al., 2011Padrón B, Nogales M, Traveset A, Vilà M, Martínez-Abraín A, Padilla DP, Marrero P. Integration of invasive Opuntia spp. by native and alien seed dispersers in the Mediterranean area and the Canary Islands. Biol Invasion. 2011;13(4):831-44.). Mycorrhizal interactions between its roots and microbes have been observed (Ervin, 2012Ervin GN. Indian fig cactus (Opuntia ficus indica (L.) Miller) in the Americas: an uncertain history. Haseltonia. 2012;17:70-81.) but so far, no detailed characterization has been done. The potential of cactus pear for fixing atmospheric nitrogen through biological nitrogen fixation (Silva et al., 2016Silva NGM, Santos MVF, Dubeux Júnior JCB, Cunha MV, Lira MA, Ferraz I. Effects of planting density and organic fertilization doses on productive efficiency of cactus pear. Rev Caatinga. 2016;29(4):976-83.) needs to be evaluated under varying simulated climatic conditions.

UTILIZATION IN HUMAN FOOD

Cactus pear fruit (nochtli) is of red color having the weight of 80-140 g of which 55% is edible portion (Cano et al., 2017Cano MP, Gómez-Maqueo A, García-Cayuela T, Welti-Chanes J. Characterization of carotenoid profile of Spanish Sanguinos and Verdal prickly pear (Opuntia ficus indica, spp.) tissues. Food Biochem. 2017;237:612-22.). It is rich in carbohydrates, vitamins, amino acids and various minerals (Table 1) which are needed in a variety of metabolic processes going on in human body (Becerra-Jiménez and Rade-Cetto, 2012Becerra-Jiménez J, Rade-Cetto A. Effect of Opuntia streptacantha Lem. on alpha-glucosidase activity. J Ethnopharm. 2012;139:493-6.). It helps in reducing oxidative damage of lipids due to vitamin C presence in abundance that assists in maintaining the redox balance (Bensadón et al., 2010Bensadón S, Hervert-Hernández D, Sáyago-Ayerdi SG, Goñi I. By-products of Opuntia ficus indica as a source of antioxidant dietary fiber. Plant Food Human Nutr. 2010;65(3):210-6. ). It has been discovered that human anti-oxidant levels may be improved over a period of time by adding its fruit in diet (Yahia and Mondragon, 2011Yahia EM, Mondragon C. Nutritional components and antioxidant capacity of ten cultivars and lines of cactus pear fruit (Opuntia spp.). Food Res Int. 2011;44:2311-8.). It may also be utilized as a natural colorant for ice cream and yoghurt preparation because of the presence of a pigment called belatins (Fernandez-Lopez et al., 2010Fernandez-Lopez JÁ, Almela L, Obón JM, Castellar R. Determination of antioxidant constituents in cactus pear fruits. Plant Food Human Nutr. 2010;65(3):253-9.). It is being used for making pulp and juice as it contains about 42% juice (Alimi et al., 2012Alimi H, Hfaeidh N, Bouoni Z, Sakly M, Ben Rhouma K. Protective effect of Opuntia ficus indica F. in prickly pear juice upon ethanol-induced damages in rat erythrocytes. Alcohol. 2012;46(3):235-43.). The consumption of cactus pear fruit was effective to regulate the sleep clock, blood pressure and served as a strong stimulant of CNS (central nervous system) (Fernandez-Lopez et al., 2010). Oil extracted from cactus pear fruit has been reported to reduce cholesterol level in a short period of time (Ciriminna et al., 2017Ciriminna R, Delisi R, Albanese L Meneguzzo F, Pagliaro M. Opuntia ficus indica seed oil: Biorefinery and bioeconomy aspects. Eur J Lipid Sci Technol. 2017;119(8). doi:10.1002/ejlt.201700013 ). In Mexico, daily intake of cactus pear has been 10-18 g person-1 year-1despite the fact that it does not constitute a complete food in itself (Hahm et al., 2011Hahm SW, Park J, Son YS. Opuntia humifusa stems lower blood glucose and cholesterol levels in streptozotocin-induced diabetic rats. Nutr Res. 2011;31:479-87.). However, it is gaining popularity in many countries including Canada, Japan, Italy, Turkey and USA for having low caloric values and higher dietary fiber content (Contreras-Padilla et al., 2012Contreras-Padilla M, Gutiérrez-Cortez E, Valderrama-Bravo MC, Rojas-Molina I, Espinosa-Arbeláez DG, Suárez-Vargas R, et al. Effects of drying process on the physicochemical properties of nopal cladodes at different maturity stages. Plant Food Human Nutr. 2012;67:44-9.).

Table 1
Nutritional status of cactus pear fruit for human utilization

Cladodes may be utilized as vegetable particularly those harvested during first year of plantation as older cladodes become hard limiting its utilization in human food. Pruning is usually required to cut closely spaced cladodes which may fulfill the shortage of vegetables in arid regions (Rodrigues et al., 2016Rodrigues AM, Pitacas FI, Reis CMG, Blasco M. Nutritional value of Opuntia ficus indica cladodes from Portuguese ecotypes. Bulgarian J Agric Sci. 2016;22:40-5.). In addition, young and immature cladodes usually during first year may also be pickled (Contreras-Padilla et al., 2012Contreras-Padilla M, Gutiérrez-Cortez E, Valderrama-Bravo MC, Rojas-Molina I, Espinosa-Arbeláez DG, Suárez-Vargas R, et al. Effects of drying process on the physicochemical properties of nopal cladodes at different maturity stages. Plant Food Human Nutr. 2012;67:44-9.). Cactus pear pads utilized as vegetable has been reported to be helpful in lowering the body weight along with being effective for lowering the blood glucose level of diabetic patients (Carreira et al., 2016Carreira VP, Padró J, Koch NM, Fontanarrosa P, Alonso I, Soto IM. Nutritional composition of opuntia sulphurea G. Don cladodes. Holestonia. 2016;19(19):38-45.). Cladodes have also been identified to have a protective influence against fatty liver (Ribeiro et al., 2010Ribeiro OEM, Silva NH, Lima Filho JL, Brito JZ, Silva MPC. Study of carbohydrates present in the cladodes of Opuntia ficus indica (fodder palm), according to age and season. Cienc Tecnol Alim. 2010;30(4):933-9.). It was also found to have a positive impact for the persistent constipation owing to its strong laxative properties (Andrade-Ceto and Wiedenfeld, 2011Andrade-Ceto A, Wiedenfeld HH. Anti-hyperglycemic effect of Opuntia streptacantha Lem. J Ethnopharm. 2011;133:940-3.). However, the problems of dermatitis (skin irritation) and conjunctivitis have been reported in humans by eating cactus pear as vegetable and fruit (Zhao et al., 2011Zhao LY, Lan QJ, Huang ZC, Ouyang LJ, Zeng FH. Antidiabetic effect of a newly identified component of Opuntia dillenii polysaccharides. Phytomedicine. 2011;18:661-8.). The nutritional composition of cactus pear fruit and cladodes are illustrated in Tables 1 and 2.

Table 2
Nutritional status of cactus pear paddles (cladodes) as vegetable for human utilization

NUTRITIVE VALUE OF CACTUS PEAR CLADODES TO SERVE AS FORAGE

Cactus pear also known by the name of forage palm can be promoted as a forage crop for arid regions (Guevara et al., 2011Guevara JC, Felker P, Balzarini MG, Páez SA, Estevez OR, Paez MN, et al. Productivity, cold hardiness and forage quality of spineless progeny of the Opuntia ficus indica 1281 x O. lindheimerii 1250 cross in Mendoza plain, Argentina. J PACD. 2011;13:48-62.). It has an extraordinary efficacy for converting water to dry matter of digestible energy (Fotius et al., 2014Fotius ACA, Ferreira MA, Bispo SV, Chaves Véras AS, Salla LE, Chagas JC. Behavior of sheep fed different sequences of ingredients in a spineless cactus (Nopalea cochenillifera Salm-Dyck) based-diet. Rev Bras Saúd Prod Anim. 2014;15:74-82.). It is the only known forage having live storage capability as it continues to grow after harvesting without deterioration in quality, (Liguori et al., 2014Liguori G, Inglese P, Sortino G, Inglese G. Dry matter accumulation and seasonal partitioning in mature Opuntia ficus indica (L.) Mill. fruiting trees. Italian J Agron. 2014;9:44-7.). Its pads may be dried and ground using a hammer-mill having 6 mm sieve to make meal for subsequent use during drought.

The nutritional quality of cactus pear depends on the age, season, climate, species, variety, soil fertility and agronomic management (Chimsa et al., 2013Chimsa MB, Mummed YY, Kurtu MY, Leta MU, Hassen A, Gemeda BS. Forage preference of camel calves (Camelus dromedarius) in eastern Ethiopia. J Anim Plant Sci. 2013;23(5):1236-41.). It ashes (10-25% of dry matter) contained calcium (85%), sodium, magnesium and potassium in the form of silica and salts along with vitamin A (Pessoa et al., 2013Pessoa RAS, Ferreira MA, Silva FM, Bispo SV, Wanderley WL, Vasconcelos PC. Different supplements associated to spineless cactus in diets for sheep: Intake, apparent digestibility and ruminal parameters. Rev Bras Saude Prod Anim. 2013;14:508-17.). Traces of iron and aluminum have also been reported in its ashes (Selmi et al., 2013Selmi H, Abdelwahed Z, Rouissi A, Jemmali B, Tayachi L, Amraoui MBD, et al. Preliminary nutritional characterization of some shrubs (Atriplex halimus, Acacia cyanophylla, Medicago arborea, Opuntia ficus indica) from the north of Tunisia. Int J Res Agric Food Sci. 2013;1:36-9.). Digestibility of cactus pear is directly dependent on the age of cladodes. The digestibility of cactus pear dry matter (70-82%) tend to be higher owing to low lignin content (50-80 g kg-1 of dried matter) (De Wall et al., 2013De Wall HO, Waal HO, Schwalbach LMJ, Combrinck WJ, Shiningavamwe KL, Els J. Commercialisation of sun-dried cactus pear (Opuntia ficus -indica) cladodes in feedlot diets for dorper wether lambs. Acta Hortic. 2013;995:343-50.) compared to forage sorghum (112-180 g kg-1 of dried matter) (Iqbal et al., 2018aIqbal MA, Iqbal A, Abbas RN. Spatio-temporal reconciliation to lessen losses in yield and quality of forage soybean (Glycine max L.) in soybean-sorghum intercropping systems. Bragantia. 2018a;77(2):283-91., bIqbal A, Iqbal MA, Hussain I, Siddiqui MH. Seed blending of oat (Avena sativa L.) and canola (Brassica napus L.) under variable seed proportions enhanced forage productivity and nutritional quality. Pak J Bot. 2018b;50:1985-90., cIqbal MA, Iqbal A, Siddiqui MH, Maqbool Z. Bio-agronomic evaluation of forage sorghum-legumes binary crops on Haplic Yermosol soil of Pakistan. Pak J Bot. 2018c;50(5):1991-7.) and canola (110-129 g kg-1 of dried matter) (Iqbal et al., 2018dIqbal MA, Iqbal A, Maqbool Z, Ahmad Z, Ali E, Siddiqui MH. Revamping soil quality and correlation studies for yield and yield attributes in sorghum-legumes intercropping systems. Biosci J. 2018d;34:1165-76.). The crude protein content is low (4-8%) with high fiber content (9-20%). Another study has reported its crude protein (CP) as 50 g kg-1 of dried matter while ruminants need CP at least 70 g kg-1 of dried matter (Soni et al., 2015Soni ML, Soni M, Yadava N. Evaluation for growth and yield performance of prickly pear cactus (Opuntia ficus indica (L.) Mill) accessions in hot arid region of Bikaner, India. Range Manage Agrof. 2015;36:19-25.). Protein quality of cladodes is satisfactory and resembled to barley grain in composition. Neutral detergent fiber (459 g kg-1 of dried matter) of spineless cactus pear has been found to be the lowest while acid detergent fiber (287 g kg-1 of dried matter) is on higher side in comparison to spiny species with dry matter degradation of 768 g kg-1 of dried matter (Cordova-Torresa et al., 2015Cordova-Torresa AV, Mendoza-Mendozaa JC, Bernal-Santosa G, García-Gascaa T, Kawasb JR, Costa RO, et al. Nutritional composition, in vitro degradability and gas production of Opuntia ficus indica and four other wild Cacti species. Life Sci J. 2015;12(2S):42-54.). Overall, the gross energy content are in the range of 3000-4000 kcal kg-1 of dry matter with digestible energy of 1800-2000 kcal kg-1 (Cordova-Torresa et al., 2015). The detailed nutritional quality of cladodes for utilization as forage has been described in Table 3.

Table 3
Nutritional status of cactus pear cladodes (nopales) for utilization as forage for ruminants.

Ruminants usually consume 20-40 kg pads per day, while it may go up to 80 kg during the drier seasons for fulfilling the water requirement (Meraz-Maldonado et al., 2012Meraz-Maldonado N. Quality of three sizes of prickly pear cactus stems (Opuntia ficus indica L. “Atlixco”). Afr J Agric Res. 2012;7(32):4512-20.). In addition, cladodes supplemented with corn-meal or cotton meal may fulfill 70% of animal’s daily requirement, however it has been suggested to restrict it to 20-30% of daily consumption on dry matter basis (Chiteva and Wairagau, 2013Chiteva R, Wairagau N. Chemical and nutritional content of Opuntia ficus indica (L.). Afr J Biotechnol. 2013;12:3309-12. ). Holstein cows were reported to lose weight when cladodes made 73% of their daily feed intake. Other studies suggested replacing alfalfa hay up to 30% with cactus pear forage (Cordão et al., 2013Cordão MA, Bakke AO, Pereira GM, Silva AMA, Nóbrega GH, Campos ÉM, et al. Substitution of Pennisetum purpureum by Opuntia ficus indica and Mimosa tenuiflora in the diet of lambs. Rev Bras Saude Prod Anim. 2013;14(4):684-94.). Small ruminants being fed on cactus pear forage have also been reported to suffer from diarrhea owing to high concentration of minerals (Andrade - Montemayor et al., 2011Andrade-Montemayor H, Torres AV, Garcia Gasca T, Kawas J. Alternative feed for small ruminants in semiarid zones, the case of Mesquite (Proposis laevigata spp.) and Nopal (Opuntia spp.). Small Rumin Res. 2011;98:83-92. ). This problem may be solved through the addition of molasses in chopped cactus pear (Ben-Salem and Ennouri, 2013Ben-Salem H, Ennouri K. Nutritive value and palatability of cladodes of spiny cactus (Opuntia amyclae) or spineless cactus (Opuntia ficus indica f. inermis) measured on adapted and non-adapted goats. Acta Hortic. 2013;995:325-30.). However, more in-depth studies are needed for determining the impact of cactus pear forage on ruminant’s performance in terms of milk and meat production.

EMERGENCY SOURCE OF WATER FOR RUMINANTS

Typically pads of cactus pear contain more than 90% water which may serve as an emergency source of water for ruminants during water scarcity conditions in arid and semi-arid regions. It has been reported that small ruminants (sheep and goat) having sufficient quantities of cladodes intake may survive up to 1.5 years without drinking water (Soni et al., 2015Soni ML, Soni M, Yadava N. Evaluation for growth and yield performance of prickly pear cactus (Opuntia ficus indica (L.) Mill) accessions in hot arid region of Bikaner, India. Range Manage Agrof. 2015;36:19-25.). This conclusion has been seconded by another study which suggests that cactus pear forage intake by sheep decrease the water intake of sheep by 93% (Isaac, 2016Isaac AA. Overview of Cactus (Opuntia ficus indica (L): A myriad of alternatives. Ethno Med. 2016;12:195-205.). However, other studies have differed by stating that animal health deteriorates when cactus pear solely provided the drinking water for a period of over 96 days (Pessoa et al., 2013Pessoa RAS, Ferreira MA, Silva FM, Bispo SV, Wanderley WL, Vasconcelos PC. Different supplements associated to spineless cactus in diets for sheep: Intake, apparent digestibility and ruminal parameters. Rev Bras Saude Prod Anim. 2013;14:508-17.; Lima et al., 2016Lima GFC, Rego MMT, Dantas FDG, Lôbo RNB, Silva JGM, Aguiar EM. Morphological characteristics and forage productivity of irrigated cactus pear under different cutting intensities. Rev Caatinga. 2016;29(2):481-8.).

IMPROVED AGRO-TECHNOLOGY PACKAGE FOR CACTUS PEAR CULTIVATION

Cactus pear has the potential to thrive well on a range of sandy to clay and clay-loam to sandy-loam soils provided its plantation is completed before rainfall (Ben-Salem and Ennouri, 2013Ben-Salem H, Ennouri K. Nutritive value and palatability of cladodes of spiny cactus (Opuntia amyclae) or spineless cactus (Opuntia ficus indica f. inermis) measured on adapted and non-adapted goats. Acta Hortic. 2013;995:325-30.; Isaac 2016Isaac AA. Overview of Cactus (Opuntia ficus indica (L): A myriad of alternatives. Ethno Med. 2016;12:195-205.; Lucivania et al., 2018Lucivania RL, Silva TGF, Jardim AMRF, Souza CAA, Queiroz MG, Tabosa JN. Growth, water use and efficiency of forage cactus-sorghum intercropping under different water depths. Rev Bras Eng Agríc Amb. 2018;22:113-8.). Transplanting of cladodes immediately after rain helps in establishing roots of the new plants and thus, before the start of monsoon rainfall was found to be the most suitable transplanting time (Grunwaldt et al., 2015Grunwaldt JM, Guevara JC, Grünwaldt EG. Review of scientific and technical bibliography on the use of Opuntia spp. as forage and its animal validation. J PACD. 2015;17:13-32. ).

Plantation at high plant density may be effective for improving biomass production per unit land area. However, for restoring pasture and rangelands, plantation at lower plant density has been recommended (Andrade - Montemayor et al., 2011; Lima et al., 2016Lima GFC, Rego MMT, Dantas FDG, Lôbo RNB, Silva JGM, Aguiar EM. Morphological characteristics and forage productivity of irrigated cactus pear under different cutting intensities. Rev Caatinga. 2016;29(2):481-8.). Varieties having high vigor, good health and reasonably higher potential for yield like South African cultivars including skinners court, Malta, Algerian, turpin, Meyers etc. (Swart et al., 2003Swart JW, Oelofse RM, Labuschagne M. Susceptibility of South African cactus pear varieties to four fungi commonly associated with disease symptoms. J PACD. 2003;86-97.) must be selected as per local agro-climatic conditions. As it is propagated through vegetative means, the planting material of cactus pear is a cutting comprising of two cladodes, of which 50-75% portion must be buried; however single cladodes cuttings may also be used in case of short supply (Soni et al., 2015Soni ML, Soni M, Yadava N. Evaluation for growth and yield performance of prickly pear cactus (Opuntia ficus indica (L.) Mill) accessions in hot arid region of Bikaner, India. Range Manage Agrof. 2015;36:19-25.; Bakali et al., 2016Bakali AH, Alem C, Ichir LL, El Mzouri H. Cladode planting methods improves the initial growth and production of cactus pear (Opuntia ficus indica (L.) Mill.). Adv Agric Bot. 2016;8(3):111-28.). Cutting must be performed on joints with a sharp knife as large wounds may become infested with pathogens (Liguori et al., 2014Liguori G, Inglese P, Sortino G, Inglese G. Dry matter accumulation and seasonal partitioning in mature Opuntia ficus indica (L.) Mill. fruiting trees. Italian J Agron. 2014;9:44-7.). In order to avoid the rotting of cladodes ends, these must be shade dried for few days to heal the wounds or treat with lime or copper sulphate solution. Shallow holes are made for burying the cladode cuttings.

Cuttings sown in rows or furrows having the spacing of 2-6 meters with cladodes-cladodes spacing of 1-2 meters have been reported to perform better than other planting geometries (Diniz et al., 2017Diniz WJS, Silva TGF, Ferreira JMS, Santos DC, Moura MSB, Araújo GGL, et al. Forage cactus-sorghum intercropping at different irrigation water depths in the Brazilian Semiarid Region. Pesq Agropec Bras. 2017;52(9):724-33. ). The optimum plant population has been found to be 2500 plant per hectare which may yield 120 and 160 tons per hectare in fifth and seventh year respectively (Lucivania et al., 2018Lucivania RL, Silva TGF, Jardim AMRF, Souza CAA, Queiroz MG, Tabosa JN. Growth, water use and efficiency of forage cactus-sorghum intercropping under different water depths. Rev Bras Eng Agríc Amb. 2018;22:113-8.). However for fertile soils, 40000 plants per hectare has been suggested, but higher plant plantation requires intensive management (Lima et al., 2016Lima GFC, Rego MMT, Dantas FDG, Lôbo RNB, Silva JGM, Aguiar EM. Morphological characteristics and forage productivity of irrigated cactus pear under different cutting intensities. Rev Caatinga. 2016;29(2):481-8.). In contrast, spineless cacti have been remained more productive when sown as 24 plants m-2 by yielding 40 t ha-1 of forage under mild drought (Meraz-Maldonado et al., 2012Meraz-Maldonado N. Quality of three sizes of prickly pear cactus stems (Opuntia ficus indica L. “Atlixco”). Afr J Agric Res. 2012;7(32):4512-20.). In contrary, Silva et al. (2016Silva NGM, Santos MVF, Dubeux Júnior JCB, Cunha MV, Lira MA, Ferraz I. Effects of planting density and organic fertilization doses on productive efficiency of cactus pear. Rev Caatinga. 2016;29(4):976-83.) have reported that the planting density of 160000 per hectare recorded the highest dry matter yield (48 t ha-1) especially with 40 tons of bovine manure application per two years. However, arid regions have recorded 5-15 ton per hectare of biomass only. There are contradictory findings regarding sowing in East-West or North-South direction (Santos-Do et al., 2016Santos TN, Dutra ED, Prado AG, Leite FCB, Souza RFR, Santos DC, et al. Potential for biofuels from the biomass of prickly pear cladodes: challenges for bioethanol and biogas production in dry areas. Biomass Bioenergy. 2016;85:215-22.). In addition, inoculation of cladodes with free-living N-fixing bacteria (sp. Nostoc) has been helpful in boosting the protein content along with providing protection again bacterial rot attack (Soni et al., 2015Soni ML, Soni M, Yadava N. Evaluation for growth and yield performance of prickly pear cactus (Opuntia ficus indica (L.) Mill) accessions in hot arid region of Bikaner, India. Range Manage Agrof. 2015;36:19-25.).

Cactus pear intercropping with sorghum has resulted in improved water use efficiency owing to lesser evapotranspiration which results in higher dry matter production (Lima et al., 2018Lima TGFS, Silva TGF, Jardim AMRF, Souza CAA, Queiroz MG, Tabosa JN. Growth, water use and efficiency of forage cactus sorghum intercropping under different water depths. Rev Bras Eng Agríc Amb. 2018;22(2):113-8.). In addition, sorghum-cactus pear intercropping reduced the time taken to harvesting from 19 to 17 months for irrigated cactus pear (Carvalho et al., 2017Carvalho AA, Silva TGF, Souza LSB, Moura MSB, Araujo GGL, Tolêdo MPS. Soil moisture in forage cactus plantations with improvement practices for their resilience. Rev Bras Eng Agríc Amb. 2017;21:481-7.; Imorim et al., 2017). Besides, cladodes length and width along with plant height and plant girth are linearly correlated to green matter yield which has direct relationship to dry matter yield (Nedar et al., 2013). First two years of plantation require pruning of closely grown cladodes which may be utilized as vegetable or forage (Ribeiro et al., 2010Ribeiro OEM, Silva NH, Lima Filho JL, Brito JZ, Silva MPC. Study of carbohydrates present in the cladodes of Opuntia ficus indica (fodder palm), according to age and season. Cienc Tecnol Alim. 2010;30(4):933-9.). Composted organic manures (20 t ha-1) or chemical fertilizers (220 kg N and 120 kg P ha-1) were effective in increasing the biomass along with protein content up to 10% of dry matter (Saenz, 2013Saenz C. Opuntias as a natural resource. In: Sáenz C, editor. Agro-industrial utilization of cactus pear. Rome: FAO; 2013. p.17-21.).

As far as harvesting systems are concerned, direct feeding of spiny Opuntia by livestock results in severe mechanical injury which may lead to death (Vilela et al., 2010Vilela MS, Ferreira MA, Azevedo M, Modesto EC, Farias I, Guimarães AV, et al. Effect of processing and feeding strategy of the spineless cactus (Opuntia fícus-indica Mill.) for lactating cows: ingestive behavior. Appl Anim Behav Sci. 2010;125:1-8.). Removal of upper edge of cladodes having the highest concentration of spines serves the purpose but results in wastage of cladodes. Harvesting may also be done through grazing or cut and carry methods, however a propane weed burner must be used to singing off spines before using as forage (Santos-Do et al., 2016Santos TN, Dutra ED, Prado AG, Leite FCB, Souza RFR, Santos DC, et al. Potential for biofuels from the biomass of prickly pear cladodes: challenges for bioethanol and biogas production in dry areas. Biomass Bioenergy. 2016;85:215-22.). Although, the burning of thorns of harvested pads with kerosene stoves was effective but sometimes it resulted in burning of cladodes along with the spines (Rodrigues et al., 2016Rodrigues AM, Pitacas FI, Reis CMG, Blasco M. Nutritional value of Opuntia ficus indica cladodes from Portuguese ecotypes. Bulgarian J Agric Sci. 2016;22:40-5.). In order to avoid this problem, spineless species have been developed and recommended to be grown. However, spineless cactus pear is needed to be protected from rodents and animals by erecting net-wire fences.

IMPLICATIONS

Due to high endurance to drought (Bakali et al., 2016Bakali AH, Alem C, Ichir LL, El Mzouri H. Cladode planting methods improves the initial growth and production of cactus pear (Opuntia ficus indica (L.) Mill.). Adv Agric Bot. 2016;8(3):111-28.; Amorim et al., 2017), cactus pear has the potential to become a noxious weed posing serious threats to cultivated areas by making the prevalent chemical, cultural, mechanical and biological control methods ineffective. In addition, the genetic resources of native plant species may also be polluted owing to its invasion in irrigated areas. Furthermore, slow growing habit and comparatively lesser hardiness to heat and cold of spineless cactus pear (O. ficus indica L. Mill.) continue to hamper its wide-scale cultivation in arid regions. Besides, it must be protected from rodents and herbivores by erecting wooden fences, wire nets or boundary walls. In contrast, spiny cactus pear does not need such protection rather requires mechanical or burning of thrones before utilization as vegetable or forage which multiplies the cost of production. It cannot tolerate water logging and soil salinity which further reduces its growth and development. Low protein content (4-5%) of cactus pear grades it poor forage on animal nutrition scale. The oxalate crystals presence reduces the provision of calcium to animals being fed on cactus pear forage. Furthermore, higher moisture content reduces the shelf life of cladodes considerably owing to being prone to microbial invasion which hinders its transportation to far-flung areas without preserving.

FUTURE BREEDING NEEDS AND TRENDS

Cactus pear with spineless pads should not be the sole goal of future breeding programs due to the fact that spines are the biggest impediment in cladodes utilization as forage. Previous studies suggested that spineless cactus pear never existed in wild while spineless species tend to revert back to spiny form gradually, despite the fact that this inheritance mode has not been identified to date (Selmi et al., 2013Selmi H, Abdelwahed Z, Rouissi A, Jemmali B, Tayachi L, Amraoui MBD, et al. Preliminary nutritional characterization of some shrubs (Atriplex halimus, Acacia cyanophylla, Medicago arborea, Opuntia ficus indica) from the north of Tunisia. Int J Res Agric Food Sci. 2013;1:36-9.). Spiny cactus pear have been found to be more rigorous, hardy, aggressive and better adapted to propagation and spread under unfavorable climatic conditions, while these characteristics are scant in spineless plants. Similarly, plant productivity may be significantly improved through breeding as suggested by differential growth of seedlings obtained from self and cross breeding. This differential growth has been attributed to alteration in photosynthesis rate and nutrient uptake (Amorim et al., 2017). However, producing more cladodes and quick recovery from pruning might serve as a crucial trait to be achieved and manipulated through breeding tools. In addition, the size of cladodes is a genetically controlled attribute (De Wall et al., 2013De Wall HO, Waal HO, Schwalbach LMJ, Combrinck WJ, Shiningavamwe KL, Els J. Commercialisation of sun-dried cactus pear (Opuntia ficus -indica) cladodes in feedlot diets for dorper wether lambs. Acta Hortic. 2013;995:343-50.) and cultivars having medium sized cladodes need to be developed for sowing in closer spacing.

Animal performance is directly linked to the nutritional quality of the feed and protein content along with the digestibility that occupies the vital position in determining the feed value. The age of cladodes determined the protein content which increased with maturity having 2.8-5.1% protein on an average (Lima et al., 2018Lima TGFS, Silva TGF, Jardim AMRF, Souza CAA, Queiroz MG, Tabosa JN. Growth, water use and efficiency of forage cactus sorghum intercropping under different water depths. Rev Bras Eng Agríc Amb. 2018;22(2):113-8.). Although protein content may be improved through appropriate agronomic management and optimal plant nutrition strategy, yet the genetic gains in terms of higher protein content must be obtained through selection and breeding. In addition, insect-pest resistance may be developed among cactus pear cultivars as it would be more viable economically and biologically to chemical control particularly against insects (stinky bugs, armored scale insect, wild cochineal, caterpillars, grasshoppers, ants etc.) and diseases (bacteria caused soft black rot and fungus caused cladode rot). Lastly, cold tolerance is another trait that must be the included as a strategic target of future genetic programs in order to enhance its tolerance to freezing temperatures. Thick integuments (epidermis, cuticle, thick walled cells and pads having crystals bearing layers) have the potential to impart resistance to heat and cold. However, it is the need of hour to focus on breeding to achieve thicker cuticle.

Cactus pear being a CAM plant has higher water and nutrient use efficiencies compared to C3 crops and C4 broadleaf plants. Both spiny and spineless cultivars have the potential to yield considerably higher quantities of green forage biomass with up to 10% protein contents if an appropriate agronomic management plan is followed with respect to transplanting time, planting geometry, fertilization and weeding. Appropriate agronomic management may lead to substantial increase in forage yield of cactus pear for bridging the gap between forage supply and demand in arid regions especially during forage scarcity periods. During drought, cactus pear may serve as a source of emergency water supply along with providing dry matter for ruminants. It may play a strategic role in conserving the ecosystem owing to its adaptability to limited growth resources. However, extensive agronomic and breeding research must be done to increase the production potential and nutritional quality of cactus pear for its cultivation in dry lands. The drastic impacts of climate change and global warming might be neutralized through wide-scale adaptation of cactus pear by reducing desertification and producing food and forage in arid areas.

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Publication Dates

  • Publication in this collection
    15 June 2020
  • Date of issue
    2020

History

  • Received
    19 Feb 2018
  • Accepted
    07 Aug 2018
Sociedade Brasileira da Ciência das Plantas Daninhas Departamento de Fitotecnia - DFT, Universidade Federal de Viçosa - UFV, 36570-000 - Viçosa-MG - Brasil, Tel./Fax::(+55 31) 3899-2611 - Viçosa - MG - Brazil
E-mail: rpdaninha@gmail.com