Abstract
The wild Malus germplasm is considered as a gene reservoir for various biotic and abiotic stresses tolerance/resistance genes, including important novel horticultural traits. The dwarf vigour is considered an important trait in Malus for promoting high-density plantations and enhancing productivity. Thus, an indigenous and exotic wild Malus species collected in the apple field gene bank were evaluated for their dwarfing potential, based on the diverse traits like stomatal features, photosynthetic pigments and anatomical structures. Among different parameters, inter-nodal length, root bark percentage, palisade: spongy tissue thickness ratio, xylem: phloem ratio, wood: bark ratio, vessel diameter of stem cross-section and photosynthetic pigments exhibited significant variation between dwarf and vigorous Malus species. The indigenous Himalayan crabapple—Malus baccata (L.) Borkh. (Rohru) showed the shortest inter-nodal length (23.82 ± 1.08 mm), low root bark percentage (69.30 ± 0.37), low xylem: phloem ratio (0.43 ± 0.01), low wood: bark ratio (0.49 ± 0.07), smaller xylem vessel diameter (9.67 ± 0.40 µm), and higher palisade: spongy tissue thickness ratio (1.25 ± 0.04) than the vigorous counterparts. These parameters were comparatively at par with the known dwarfing rootstock M.9. The foliar photosynthetic pigments content was significantly higher in M. baccata (Rohru) compared to other studied Malus species. Furthermore, stomatal density showed much dependence on the size of stomata, specifically its length rather than the vigour of Malus genotypes. The study revealed that Malus baccata (Rohru) had several dwarfing attributes which were comparable to the dwarfing rootstock M.9 and thus could serve as an important genetic resource for the development of indigenous dwarfing rootstock.
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References
Aneesa RMS, Kumar N, Marimuthu R (2011) Evolving cashew F1 hybrids suitable for high density planting system. Indian J Hortic 68(2):152–155
Anonymous (1962) The wealth of India: raw materials. CSIR New Delhi VI, pp 234–249
Atkinson C, Else M (2001) Understanding how rootstocks dwarf fruit trees. Compact Fruit Tree 34(2):46–49
Atkinson CJ, Else MA, Taylor L, Dover CJ (2003) Root and stem hydraulic conductivity as determinants of growth potential in grafted trees of apple (Malus pumila Mill.). J Exp Bot 54(385):1221–1229
Barnes JD, Balaguer L, Manrique E, Elvira S, Davison AW (1992) A reappraisal of the use of DMSO for the extraction and determination of chlorophylls a and b in lichens and higher plants. Environ Exp Bot 32(2):85–100
Basile B, Marsal J, DeJong TM (2003) Daily shoot extension growth of peach trees growing on rootstocks that reduce scion growth is related to daily dynamics of stem water potential. Tree Physiol 23(10):695–704
Beakbane BA, Majumder PK (1975) A relationship between stomatal density and growth potential in apple rootstocks. J Hortic Sci 50(4):285–289
Beakbane BA, Thompson EC (1947) Anatomical studies of stems and roots of hardy fruit trees. IV. The root structure of some new clonal apple rootstocks budded with Cox’s Orange Pippin. J Pomol Hortic Sci 23(4):206–211
Bruckner CH, DeJong TM (2014) Proposed pre-selection method for identification of dwarfing peach rootstocks based on rapid shoot xylem vessel analysis. Sci Hortic 165:404–409
Chen B, Wang C, Tian Y, Chu Q, Hu C (2015) Anatomical characteristics of young stems and mature leaves of dwarf pear. Sci Hortic 186:172–179
Cui M, Vogelmann TC, Smith WK (1991) Chlorophyll and light gradients in sun and shade leaves of Spinacia oleracea. Plant Cell Environ 14(5):493–500
Curran PJ, Dungan JL, Gholz HL (1990) Exploring the relationship between reflectance red edge and chlorophyll content in slash pine. Tree Physiol 7:33–48
Dayan J, Voronin N, Gong F, Sun TP, Hedden P, Fromm H, Aloni R (2012) Leaf-induced gibberellin signaling is essential for internode elongation, cambial activity, and fiber differentiation in tobacco stems. Plant Cell 24(1):66–79
El Said SH, Hegazi AA, Allatif AM (2013) Histological indicators of dwarfism of some olive cultivars. World Appl Sci J 28(6):835–841
FAOSTAT (2019). http://www.fao.org/faostat/en/#data/QC. Accessed on 4 Apr 2019
Filella I, Serrano L, Serra J, Penuelas J (1995) Evaluating wheat nitrogen status with canopy reflectance indices and discriminant analysis. Crop Sci 35(5):1400–1405
Harrison N, Harrison RJ, Barber-Perez N, Cascant-Lopez E, Cobo-Medina M, Lipska M, Conde-Ruíz R, Brain P, Gregory PJ, Fernández-Fernández F (2016) A new three-locus model for rootstock-induced dwarfing in apple revealed by genetic mapping of root bark percentage. J Exp Bot 67(6):1871–1881
Hollender CA, Hadiarto T, Srinivasan C, Scorza R, Dardick C (2016) A brachytic dwarfism trait (dw) in peach trees is caused by a nonsense mutation within the gibberellic acid receptor PpeGID1c. New Phytol 210(1):227–239
Hooker JD (1879) The flora of British India. II L Reeve and Co Ltd NR, Ashford, Kent, England
Johansen DA (1940) Plant microtechnique. McGraw-Hill, New York
Juniper BE, Watkins R, Harris SA (1998) The origin of the apple. Acta Hortic 484:27–34
Kishore DK, Randhawa SS (1993) Wild germplasm of temperate fruits. In: Chadha KL, Pareek OP (eds) Advances in horticulture vol 1 - fruit crops part 1. Malhotra Publishing House, New Delhi, pp 227–241
Kishore DK, Pramanick KK, Singh AK, Singh R, Verma JK (2015) Chilling unit accumulation at Shimla, Himachal Pradesh, India—a predominantly apple (Malus× domestica Borkh) growing region. Int J Fruit Sci 15(2):117–128
Kumar C, Singh SK, Pramanick KK, Verma MK, Srivastav M, Singh R, Bharadwaj C, Naga KC (2018) Morphological and biochemical diversity among the Malus species including indigenous Himalayan wild apples. Sci Hortic 233:204–219
Kumar C, Singh SK, Singh R, Pramanick KK, Verma MK, Srivastav M, Tiwari G, Choudhury DR (2019) Genetic diversity and population structure analysis of wild Malus genotypes including the crabapples (M. baccata (L.) Borkh. & M. sikkimensis (Wenzig) Koehne ex C. Schneider) collected from the Indian Himalayan region using microsatellite markers. Genet Resour Crop Ev 66(6):1311–1326
Kurian RM, Iyer CP (1992) Stem anatomical characters in relation to tree vigour in mango (Mangifera indica L.). Sci Hortic 50(3):245–253
Liang M, Ge H (2009) Comparison of leaf structure and chloroplast ultrastructure between columnar and standard apples. Acta Hortic Sin 36(10):1504–1510
Liang M, Ge H (2010) Studies on the leaf epidermal structure of columnar apple and dwarf pear seedlings in vitro. J Fruit Sci 27(1):1–7
Ljubojević M, Zorić L, Maksimović I, Dulić J, Miodragović M, Barać G, Ognjanov V (2017) Anatomically assisted cherry rootstock selection. Sci Hortic 217:197–208
Lockard RG (1976) The effect of apple dwarfing rootstocks and interstocks on the proportion of bark on the tree. Hortic Res 15:83–94
Majumdar PK, Chakladar BP, Mukherjee SK (1972) Selection and classification of mango rootstocks in the nursery stage. In: Symposium on mango and mango culture, vol 24, pp 101–106
Marini RP, Black B, Crassweller RM, Domoto PA, Hampson C, Johnson S, Kosola K, McArtney S, Masabni J, Moran R, Quezada RP (2009) Performance of “Golden Delicious” apple on 23 rootstocks at 12 locations: a five-year summary of the 2003 nc-140 dwarf rootstock trial. J Am Pomol Soc 68(2):54–68
Mosse B (1952) A study of the bark-wood relationship in apple stems. Annual Report, East Malling Research Station for 1955, pp 70–75
Nafees M, Jaskani MJ, Ahmad S, Shahid M, Malik Z, Jamil M (2017) Biochemical diversity in wild and cultivated pomegranate (Punica granatum L.) in Pakistan. J Hortic Sci Biotech 92(2):199–205
Pandit AH, Sofi AA, Verma MK, Pandit BA (2004) Leaf stomata as a bio-indicator of plant vigor in apple (Malus x domestica) rootstock species and their ecotypes. Environ Ecol 22:270–273
Pathak RK, Pandey D, Pandey VS (1976) Stomatal distribution as an index for predicting the growth potential of apple stocks. J Hortic Sci 51(3):429–431
Rana JC, Pradheep K, Verma VD (2007) Naturally occurring wild relatives of temperate fruits in Western Himalayan region of India: an analysis. Biodivers Conserv 16(14):3963–3991
Randhawa SS (1987) Wild germplasm of pome and stone fruits. IARI Regional Station, Shimla, Himachal Pradesh, India
Randhawa SS, Kishore DK (1986) Preliminary evaluation of native Malus baccata types as rootstock. In: Advances in research on temperate fruits. Chadha TR, Bhutani VP, Kaul JL (eds) Dr. YS Parmar University of Horticulture and Forestry, Solan, Himachal Pradesh [India]
Rashedy AA, El Kheshin MA, Allatif AA (2014) Histological parameters related to dwarfism in some mango cultivars. World J Agric Sci 10(5):216–222
Reinhardt D, Mandel T, Kuhlemeier C (2000) Auxin regulates the initiation and radial position of plant lateral organs. Plant Cell 12(4):507–518
Robinson TL (2007) Recent advances and future directions in orchard planting systems. In: VIII International symposium on canopy, rootstocks and environmental physiology in orchard systems, Acta Hortic vol. 732, pp 367–381. https://doi.org/10.17660/ActaHortic.2007.732.57
Russo NL, Robinson TL, Fazio G, Aldwinckle HS (2007) Field evaluation of 64 apple rootstocks for orchard performance and fire blight resistance. HortSci 42(7):1517–1525
Saeed M, Dodd PB, Sohail L (2010) Anatomical studies of stems, roots and leaves of selected citrus rootstock varieties in relation to their vigour. J Hortic for 2(4):87–94
Santner A, Calderon-Villalobos LI, Estelle M (2009) Plant hormones are versatile chemical regulators of plant growth. Nat Chem Biol 5(5):301
Seleznyova A, Thorp G, White M, Tustin S, Costes E (2004) Structural development of branches of 'Royal Gala' apple grafted on different rootstocks/ interstock combinations. Acta Hortic 636: 173–180
Sharma DP, Sharma YD, Rana HS (1982) Stomatal and tree growth characteristics of some crab apples. Sci Hortic 17(4):327–331
Sharma SK, Kishore DK, Pramanick KK (2006) Utilization of indigenous crab apples for the management of foliar and soil borne diseases. In Ghosh S N, Mitra SK, Banik BC, Hasan MA, Sarkar SK, Dhua RS, Kabir J, Hore J K (eds), Proceedings of the national symposium on production, utilization and export of underutilized fruits with commercial potentialities. Kalyani, Nadia, West Bengal, India, pp 205–208
Srivastava KK, Singh DB, Kumar D, Mir JI (2016) Screening of exotic and indigenous apple rootstocks for different horticultural traits. SAARC J Agric 14(2):117–125
Talwara S, Grout BW, Toldam-Andersen TB (2013) Modification of leaf morphology and anatomy as a consequence of columnar architecture in domestic apple (Malus× domestica Borkh.) trees. Sci Hortic 164:310–315
Terashima I, Saeki T (1983) Light environment within a leaf I. Optical properties of paradermal sections of Camellia leaves with special reference to differences in the optical properties of palisade and spongy tissues. Plant Cell Physiol 24(8):1493–1501
Tombesi S, Johnson RS, Day KR, DeJong TM (2009) Relationships between xylem vessel characteristics, calculated axial hydraulic conductance and size-controlling capacity of peach rootstocks. Ann Bot 105(2):327–331
Tombesi S, Almehdi A, DeJong TM (2011) Phenotyping vigour control capacity of new peach rootstocks by xylem vessel analysis. Sci Hortic 127(3):353–357
Trifilò P, Gullo MA, Nardini A, Pernice F, Salleo S (2007) Rootstock effects on xylem conduit dimensions and vulnerability to cavitation of Olea europaea L. Trees 21(5):549–556
Tworkoski T, Miller S (2007) Rootstock effect on growth of apple scions with different growth habits. Sci Hortic 111(4):335–343
Wang SY, Faust M (1987) The relationship of internode length to carbohydrate content in genetic dwarf apple trees. Sci Hortic 33(3–4):197–203
Wang CH, Tian YK, Chu QG, Zhang XQ, Sun TJ (2005) Study on the leaf anatomical structure of columnar apples. J Fruit Sci 22:311–314
Webster AD (2004) Vigour mechanisms in dwarfing rootstocks for temperate fruit trees. In: I International symposium on rootstocks for deciduous fruit tree species. Acta Hortic 658: 29–41
Weibel A, Johnson RS, DeJong TM (2003) Comparative vegetative growth responses of two peach cultivars grown on size-controlling versus standard rootstocks. J Am Soc Hortic Sci 128(4):463–471
Zhang YG, Dai HY (2011) Comparison of photosynthetic and morphological characteristics, and microstructure of roots and shoots, between columnar apple and standard apple trees of hybrid seedlings. Phyton-Rev Int Bot Exp 80:119–125
Zorić L, Ljubojević M, Merkulov L, Luković J, Ognjanov V (2012) Anatomical characteristics of cherry rootstocks as possible preselecting tools for prediction of tree vigor. J Plant Growth Regul 31(3):320–331
Acknowledgements
The senior author duly acknowledges the Post Graduate School, ICAR- Indian Agricultural Research Institute, New Delhi, to provide research facilities and the Department of Science and Technology, Government of India, to provide INSPIRE Fellowship. The authors sincerely acknowledge the Director and Dr S.K. Malik, ICAR-NBPGR, New Delhi, for providing microtome facilities.
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Kumar, C., Singh, S.K., Verma, M.K. et al. Morpho-physio and anatomical characterization of the indigenous Himalayan crabapple: Malus baccata (L.) Borkh. (Rohru) and exotic Malus pumila Mill. for dwarfing traits. Genet Resour Crop Evol 69, 645–659 (2022). https://doi.org/10.1007/s10722-021-01250-0
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DOI: https://doi.org/10.1007/s10722-021-01250-0