Morpho-genetic profiling and phylogenetic relationship of guava (<i>Psidium guajava</i> l.) as genetic resources in Pakistan

Kareem, Abdul; Jaskani, Muhammad Jafar; Mehmood, Asim; Khan, Iqrar Ahmad; Awan, Faisal Saeed; Sajid, Muhammad Wasim

doi:10.1590/0100-29452018069

Abstract

Guava (Psidium guajava L.) is an open-pollinated crop having 25-40% dissimilarity index which promotes heterozygosity and adds new cultivars. Morpho-genetic characterization of 37 guava accessions was carried out for genetic variability and structure of guava germplasm located in Punjab province, Pakistan. Principal Component analysis (PCA) was subjected to analyze the morphological diversity and for genetic analysis we applied cluster analysis, using the PyElph software. PCA distributed thirty one traits into six components and first two components accounted 39.5% of total variation. A dendrogram constructed on the basis of morphological traits which showed 34% dissimilarity index among thirty seven guava accessions and divided them into 6 groups. For genetic characterization 18 microsatellites were used, the size of reproducible and scorable bands ranged from 150 to 320 bp. The 18 primer pairs amplified 85 alleles with an average number of 4.7 alleles per locus and no more than two displayed bands (nuclear SSR loci). The phylogenetic tree based on molecular analysis showed 50% dissimilarity index among selected guava accessions and separated them into 4 groups.

Index terms
cross pollinated; dendrogram; genetic diversity; reproducible; SSR markers

Resumo

A goiaba (Psidium guajava L.) é uma cultura de polinização aberta tendo 25-40% Índice de dissimilaridade que promove a heterozigosidade e acrescenta novas cultivares. Caracterização morfo-genética de 37 acessos de goiabeira foi realizada para a variabilidade genética e estrutura de germoplasma de goiaba localizado na província Punjab, Paquistão. A análise de componentes principais (PCA) foi submetida para analisar a diversidade morfológica e para análises genéticas foram aplicados a análise de agrupamento, utilizando o software de PyElph. PCA traços distribuídos trinta e um em seis componentes e dois primeiros componentes representaram 39,5% da variação total. Um dendrograma construído com base em caracteres morfológicos que mostrou 34% de índice de dissimilaridade entre trinta e sete acessos de goiabeira e dividiu-os em 6 grupos. Caracterização genética de 18 microssatélites foram utilizados, o tamanho dos gerados reprodutível e bandas variou de 150 a 320 pb. Os 18 pares de primers amplificado 85 alelos, com uma média de 4,7 alelos por loco e não mais do que duas bandas exibido (locos SSR nuclear). A árvore filogenética baseada na análise molecular mostrou 50% de índice de dissimilaridade entre os acessos de goiabeira selecionados e separados em 4 grupos.

Termos para indexação
polinização cruzada; o dendrograma; diversidade genética; reprodutível; marcadores SSR

Introduction

Guava (Psidium guajava) is an important tropical fruit crop which belongs to family Myrtaceae. It is the hardiest among tropical fruits and excels most of the other fruit crops in productivity and adaptability. The family Myrtaceae is comprised of 142 genera and more than 6700 species of trees and shrubs (KUBITZKI et al. 2010 KUBITZKI, K.; KALLUNKI, J.A.; DURETTO, M.; WILSON, P.G. Rutaceae. In: KUBITZKI, K. (Ed.). The families and genera of vascular plants. Berlin: Springer, 2010. v.10. ). Botanically, guava fruit is a berry which may be rounded, ovate, or pear shaped. The fruit varies from 25 to 102 mm in diameter and from 56 to about 450 g in weight.

The skin color of the ripe fruit is usually yellow and the flesh color may be white, pink, yellow or cream. Guavas vary from thick fleshed fruits with only a few seeds in a small central cavity, to thin fleshed fruits with numerous seeds imbedded in a large mass of pulp. The fruits range in flavor from quite sweet in some varieties, to sour and highly acidic in others. The characteristic musky guava aroma and flavor are quite evident in most forms, however in some types they are milder and more pleasant. In others, the aroma and flavor may be too strong and penetrating for most tastes (MENZEL, 1985 MENZEL, C.M. Guava: an exotic fruit with potential in Queensland. Queensland Agricultural Journal, Brisbane, v.111, p. 93-98, 1985. ).

India has the world’s largest mass production of guava, followed by Pakistan, Mexico, Brazil, Egypt, Thailand, Columbia, and Indonesia. Production in these countries has increased 10-fold in the last five years (POMMER and MURKAMI, 2009 POMMER, C.V.; MURKAMI K.R.N. Breeding guava (Psidium guajava L.). In: JAIN, S.M.; PRIYADARSHAN, P.M. (Ed.). Breeding plantation tree crops: tropical species. New York: Springer, 2009. p.83-120. ). In Pakistan, guava is extensively grown in Punjab and Sindh provinces and occupies third position after citrus and mango in terms of area and production. The two main types of cultivated guava in Pakistan are Gola (round shape fruit) and Surahi (pear shape fruit). According to the Pakistan Statistical Year book (2010) PAKISTAN STATISTICAL YEARBOOK. Federal bureau of statistics. Islamabad: Ministry of Economic Affairs and Statistics, Government of Pakistan, 2010. , guava is grown on 62,300 ha giving 512,300 t of annual production with a yield of 8223 kg per hectare. Punjab province grew 49,700 ha with a total production of 422,300 t and yield of 8497 kg per hectare. Although guava is cultivated across a large area, its production remains low, probably due to a lack of superior varieties along with other environmental and disease stresses (IMRAN et al., 2013 IMRAN, H.; MUHAMMAD, S.; SAJID, A.K.; MUHAMMAD, J.J.; Zia, U. Occurrence of guava anthracnose in Punjab (Pakistan) and its integrated management. Pakistan Journal of Agricultural Sciences, Faisalabad, v.50, p.707-710, 2013. ).

By comparison, however, local growers in Pakistan replenish their trees from sexual propagation (propagation from seed). No commercial cultivars are available. Since these growers name their cultivars according to a few morphological characters and locality, the naming system is confused. Accurate characterization of guava cultivars and rootstocks is essential for commercial orchards and nurseries as this can guarantee uniformity in the establishment of new orchards (PAKISTAN STATISTICAL YEARBOOK, 2010 PAKISTAN STATISTICAL YEARBOOK. Federal bureau of statistics. Islamabad: Ministry of Economic Affairs and Statistics, Government of Pakistan, 2010. ). This can be supported by inclusion of DNA-based markers (such as the iPBS and SSR marker systems) for germplasm characterization to provide more basic genetic information. As markers are not affected by the environment, conclusions and interpretations regarding genetic variation will be more reliable (SANCHEZTEYER et al., 2010 SANCHEZ-TEYER, L.F.; BARRAZA-MORALES, A.; KEB, L.; BARREDO, F.; QUIROZ-MORENO, A.; O’CONNOR-SANCHEZ, A.; PADILLA-RAMIREZ, J.S. Assessment of genetic diversity of Mexican guava germplasm using DNA molecular markers. Acta Horticulturae, Leuven, v.849, p.133-138, 2010. ). According to analyses performed to evaluate the genetic diversity among Passiflora accessions, it was inferred that gathering knowledge about aspects of the germination of seeds of several passion fruit species, especially wild species, is fundamental for the propagation and maintenance of germplasm banks (THALITA et al. 2017 THALITA, N.M.; LOURISMAR, M.A.; PETTERSON, B.L.; LEONARDA, G.N.; MARCO, A.A.B. Genetic diversity of Passiflora accessions based on morphophysiological seed descriptors. Revista Brasileira de Fruticultura, Jaboticabal, v.39, n.5, p.e-365, 2017. ).

Genetic diversity and discrimination among individual accessions or groups of individuals or populations can be analyzed by a specific method or a combination of methods (MEHMOOD et al., 2014 MEHMOOD, A.; JASKANI, M.J.; KHAN, I.A.; AHMAD, S.; AHMAD, R.; AHMAD, N.M.; LUO, S. 2014. Genetic diversity of Pakistani guava (Psidium guajava L.) germplasm and its implications for conservation and breeding. Scientia Horticulturae, Wageningen, v.172, p.221-232, 2014. ; RITTER, 2012 RITTER, E. Guava biotechnologies, genomic achievements and future needs. Acta Horticulturae, Leuven, v. 959, p. 131-140, 2012. ; VALDE´S-INFANTE et al., 2010 VALDÉS-INFANTE, J.; RODRIGUEZ, N.N.; VELASQUEZ B.; RIVER, D.O.; MARTINEZ, F.; ESPINOSA, G.; RISTERUCCI, A.M.; BILLOTTE, N.; BECKER, D.; ROHDE, W. 2010. Simple sequence repeats SSRs for diversity characterization of guava Psidium guajava L. Acta Horticulturae, Leuven, v.849, p.155-162, 2010. ).

Different molecular markers such as AFLP (SANCHEZTEYER et al., 2010 SANCHEZ-TEYER, L.F.; BARRAZA-MORALES, A.; KEB, L.; BARREDO, F.; QUIROZ-MORENO, A.; O’CONNOR-SANCHEZ, A.; PADILLA-RAMIREZ, J.S. Assessment of genetic diversity of Mexican guava germplasm using DNA molecular markers. Acta Horticulturae, Leuven, v.849, p.133-138, 2010. ; VALDE´S-INFANTE et al., 2003 VALDÉS-INFANTE, D.; BECKER, D.; RODRÍGUEZ, N.; VELÁZQUEZ, B.; GONZÁLEZ, G.; SOURD, D.; RODRÍGUEZ, J.; RITTER, E.; ROHDE, W. Molecular characterization of Cuban accessions of guava (Psidium guajava L.), establishment of a first molecular linkage map and mapping of QTLs for vegetative characters. Journal of Genetics and Breeding, Italy, v.57, p.349-358, 2003. ), ISTR , RAPD (AHMED et al., 2011 AHMED, B.; MANNAN, M.A.; HOSSAIN, S.A. Molecular characterization of guava (Psidium guajava L.) germplasm by RAPD analysis. International Journal of Natural Sciences, Bangladesh, v.1, p.62-67, 2011. ; COSER et al., 2012 COSER, S.M.; DA SILVA FERREIRA, M.F.; FERREIRA, A.; MITRE, L.K.; CARVALHO, C.R.; CLARINDO, W.R. Assessment of genetic diversity in Psidium guajava L. using different approaches. Scientia Horticulturae, Wageningen, v.148, p.223-229, 2012. ), iPBS (MEHMOOD et al., 2013 MEHMOOD, A.; JASKANI, M.J.; AHMAD, S.; AHMAD, R. Evaluation of genetic diversity in open pollinated guava by iPBS primers. Pakistan Journal of Agricultural Sciences, Faisalabad, v.50, p.591-59, 2013. ) SSR (ARANGUREN et al., 2010 ARANGUREN, Y.; BRICENO, A.; FERMIN, G. Assessment of the variability of Venezuelan guava landraces by microsatellites. Acta Horticulturae, Leuven, v.849, p.147-154, 2010, ) have so far been used for guava germplasm analysis. Among these different types of molecular markers, microsatellites or SSRs (defined as short tandem repeats) have been widely used in different countries as efficient tools for germplasm characterization, for plant management and for diversity studies on Psidium germplasm (BRICENO et al., 2010 BRICENO, A.; ARANGUREN, Y.; FERMIN, G. Assessment of guavaderived SSR markers for the molecular characterization of Myrtaceae from different ecosystems in Venezuela. Acta Horticulturae, Leuven, v.849, p.139-146, 2010. ). Therefore, the objective of this work was to evaluate genetic diversity based on molecular markers and morphological characterization that intended to help breeding program and identification of genotypes from Pakistan.

Material and methods

Plant materials Thirty-seven seed propagated guava accessions were selected from the hub of guava growing districts included Faisalabad and Sheikhupura of Punjab province, Pakistan (Table 1, Figure 1). The accessions were selected based on fruit size, fruit shape, flesh color, fruit blush color and number of seeds.

Evaluation of morphological traits Thirty-one morphological traits were selected for genetic diversity of guava accessions by using guava plant descriptors (UPOV, 1987 UPOV. Guidelines for the conduct of tests for distinctness, homogeneity and stability. Guava (Psidium guajava L.). Geneva, 1987. p.29. (TG/110/3) ); fully developed shoot, leave and fruit were selected for data collection. Studied traits included young shoot color, thickness of stem (mm), length of leaf blade (mm), width of leaf blade (mm), leaf blade length/ width ratio (%), leaf shape, leaf curvature in cross section, leaf green color, leaf color of midrib on lower side, leaf spacing of secondary veins, leaf relief of surface of upper side, the shape of leaf base, the shape of leaf tips, fruit length (mm), fruit width (mm), fruit length/ width ratio (%), fruit shape at stalk end, fruit width of neck in relation to that of fruit, fruit skin color, fruit relief of surface, fruit size (g), fruit cavity diameter (mm), fruit ridged on skin, fruit stalk length (mm), fruit flesh color, thickness of outer flesh (mm), fruit Juiciness, fruit acidity, TSS (°Brix), seed weight (g), number of seeds.

DNA extraction for molecular studies The genomic DNA from 2 g of fresh and healthy leaves were extracted by following the modified CTAB method (MURRAY and THOMPSON, 1980 MURRAY, M.; THOMPSON, W.F. Rapid isolation of high molecular weight plant DNA. Nucleic Acids Research, London, v.8, p.4321-4326, 1980. ).

PCR amplification Eighteen microsatellite markers (RISTERUCCI et al., 2005 RISTERUCCI, A.M.; DUVAL, M.F.; ROHDE, W.; BILLOTTE, N. Isolation and characterization of microsatellite loci from Psidium guajava L. Molecular Ecology Notes, Oxford, v.5, p.745-748, 2005. ) were used for genetic amplification of 37 guava accessions using the method of RODRÍGUEZ–MEDINA et al. (2007) RODRÍGUEZ–MEDINA, N.N.; INFANTE J.V.; VELASQUEZ, B.; RIVERO, D.; MARTINEZ, F.; RISTERUCCI, A.M.; BILLOTTE, N.; BECKER, D.; RITTER, E.; ROHDE, W. 2007. Individual versus combined data set for molecular characterization of Cuban guava Psidium guajava germplasm. Acta Horticulturae, Leuven, v.849, p.163-172, 2007. . PCR amplifications were accomplished in 20 μL reaction mixture using thermal cycler (PERKIN ELMER MODEL 480). The PCR reaction mixture contained template DNA (20 ng), 1μM each primer, 200 μM of dNTPs, and 1X gold PCR buffer, 0.5U Taq (Ampli Taq Gold DNA polymerase) and MgCl2 solution (2mM).

The optimization of conditions was made separately for each marker. All markers were tested on DNA samples at the annealing temperature of 55°C, whereas all other conditions of procedure were kept constant: 5 min at 94°C; 35 cycles of 30sec at 94°C, 45sec at 56°C and 2 min at 72°C and final extension was done for 4 min at 72 °C.

The confirmation of all amplifications was performed by running PCR product (5μL) on agarose gels (2%).

Data analysis Morphological data were subjected to Principal Component Analysis (PCA) (FRANCO and HIDALGO, 2002 FRANCO, T.; HIDALGO, R. Análisis estadístico de datos de caracterización morfológica. Rome: IPGRI, 2002. (Technical Bulletin, 8) ) in order to identify morphological variables. Data analysis was performed using statistical software Statistica 5.5 version. For molecular analysis, PCR was performed three times to confirm band pattern for each primer. DNA bands were sized and scored by Lab Works software (v4.5, UVP) and carefully checked manually; only clear bands were scored and faint bands were ignored. Bands with the same size were assumed to represent a single locus. For each locus data were recorded using ‘1’ for presence of a band and ‘0’ for absence so as to build a binary matrix.

Assessment of genetic relationship among the accessions was done by cluster analysis, using the PyElph software, version 1.4 .

Results and discussion

Characterization of morphological traits using PCA Principal Component analyses (PCA) distributed thirty-one traits into six components that explained 73.91% variation. The first two components have major contribution of total variation, first component accounted for 25.14 % of the total variation, included leaf curvature in cross section, leaf spacing of secondary veins, leaf shape of base, shape of leaf tips, fruit length/width ratio, fruit width, fruit length, seed weight, fruit size, fruit diameter, fruit ridges on skin, fruit length of stalk, fruit juiciness, total soluble solid, number of seeds and fruit relief of surface. The second component, which explained 14.26% of total variation, included young shoot color, fruit diameter of cavity, fruit color of flesh, leaf curvature in cross section, leaf color of midrib on lower side, leaf spacing of secondary veins, leaf shape of base, fruit ridges, leaf shape and fruit acidity. A 2D PCA plot was constructed on the basis of first two components (Figure 1). The 2D plot distributed the guava accessions according to their phenotypic resemblance and morphological characteristics. The accessions number A4, A5, A19 and A33 were grouped together with the highest fruit weight, the longest fruit length and the longest fruit width while accessions number A6, A12 and A28 with the pink flesh were group together. Similarly the accessions having distinct morphological trait are separated from others like A29 with small size, pear shape A21 with small size, round shape and A3 with grooves on skin. These results showed that the fruit weight, fruit width, fruit length, fruit size and flesh color are highly positively correlated and as a result these traits led to the highest loading factors in this PCA analysis.

According to Rodríguez-Medina et al. (2007) RODRÍGUEZ–MEDINA, N.N.; INFANTE J.V.; VELASQUEZ, B.; RIVERO, D.; MARTINEZ, F.; RISTERUCCI, A.M.; BILLOTTE, N.; BECKER, D.; RITTER, E.; ROHDE, W. 2007. Individual versus combined data set for molecular characterization of Cuban guava Psidium guajava germplasm. Acta Horticulturae, Leuven, v.849, p.163-172, 2007. and Andrés-Agustin et al. (2006) ANDRÉS-AGUSTÍN, J.; GONZÁLEZ-ANDRÉS F.R.; NIETO-ÁNGEL R.; BARRIENTOS-PRIEGO A.F. Morphometry of the organs of cherimoya (Annona cherimola Mill.) and analysis of fruit parameters for the characterization of cultivars, and Mexican germplasm selection. Scientia Horticulturae, Wageningen, v.4, p.337-346, 2006. these traits are valuable for identification of guava populations and other horticultural fruits. Most of the traits studied are economically important for plant breeders, especially thickness of outer flesh in relation to core diameter, fruit length, fruit width and fruit juiciness. Our study supports the view that phenotypic traits in fruits are helpful for accessions or cultivar identification and are reliable in establishing the genetic relationships across larger and diverged accessions of guava (PADILLA-RAMIREZ AND GONZALEZGAONA, 2010 PADILLA-RAMIREZ, J.S.; GONZALEZ-GAONA, E. Collection and characterization of Mexican guava (Psidium guajava L.) germplasm. Acta Horticulturae, Leuven, v.849, p.49-54, 2010. ; MEHMOOD et al., 2014 MEHMOOD, A.; JASKANI, M.J.; KHAN, I.A.; AHMAD, S.; AHMAD, R.; AHMAD, N.M.; LUO, S. 2014. Genetic diversity of Pakistani guava (Psidium guajava L.) germplasm and its implications for conservation and breeding. Scientia Horticulturae, Wageningen, v.172, p.221-232, 2014. ).

Similarity matrix and dendrogram based on morphological traits Ward linkage method used to construct dendrogram which differentiated 37 guava accessions into two main groups and second group is further divided into 5 groups (Figure 2). Group A contained two guava genotypes with low seeded and round shape fruits. Group B is further divided into six subgroups B1, B2, B3, B4, B5 and B6.

B1 contained four guava accessions with round shape and large size fruit, B2 had eight accessions with pear shape and medium size fruit, B3 contained six guava accessions with pear and round shape fruit, B4 had four genotypes which had pink blush (Psidium cattleianum), B5 had three guava accessions which had round shape and small size, B6 contained ten guava accessions which had round shape, medium size and white pulp. The main and sub groups diversity provides the general information of varietal performance and relationship according to their environment; however, this diversity is dependent on geographical origin and or even pedigree relations, and accessions that display high phenotypic dissimilarity might not to be genetically dissimilar because the environment can manipulate phenotypic expressions (POEHLMAN, 1987 POEHLMAN, J. M. Breeding field crops. 3rd ed. New York: Springer Publication, 1987. p.15-25. ). Similar results were reported by Junior et al. (2008) JUNIOR, J.F.S.; BEZERRA, J.E.F.; TAVARES, J.A.; LEDERMAN, I.E.; DE MELO-NETO, M.L.; NETO, L.G. Caracterización y evaluación de germoplasma de Guayabo (Psidium guajava L.) en la región semiárida del Estado de Pernambuco, Brasil. Revista Caatinga, Mossoró, v.21, p.94-99, 2008. that evaluated 63 accessions of guava and found accessions Compos and Coma the most divergent with other closely associated accessions and morphological traits. The reasoning for solitary clusters formation is due to complete inhibition and isolation of gene flow or either may be due to severe natural/human selection procedure of accessions for divergence abortiveness.

DNA polymorphism generated by 18 SSR primers and phylogenetic relationship Eighteen guava-specific microsatellite primer pairs were used to screen the 37 guava accessions for genetic identification. Significant molecular variability was detected among all accessions (Table 2). The size of reproducible and scorable bands ranged from 150 to 320 bp. The 18 primer pairs amplified 85 alleles with an average total number of 4.7 alleles per locus and no more than two displayed bands (nuclear SSR loci). The Phylogenetic relatedness based on 18 microsatellites of 37 guava accessions defined genetic diversity among guava accessions. The dendrogram generated by PyElph software separated thirty seven guava accessions into four main groups (group A, group B, group C and group D), group A is further divided into A-1that constituted 2 guava accessions and A-2 that consisted 6 guava accessions similarly group B is sub-divided into B-1 that contained 3 guava accessions, group B-2 that had 1 guava accessions and B-3 that had 8 guava accessions further group C had 6 guava accessions and group D contained 11 guava accessions (Figure 3). Within the species P. guajava, SSR systems separated the 37 guava accessions into clusters according geographical regions; level of information generated suggests that accessions collected from the same geographical region or breeding program tended to group together, indicating that despite the widespread distribution of guava in the tropical world and more than 100 years of cultivation, germplasm exchange among regions has been limited. Furthermore, results from this study showed that only a small number of guava cultivars have been used in breeding programs. In Pakistan, guava breeding is highly dependent on seed propagation with subsequent selection being made according to specific characteristics like fruit quality and/or plant vigour according to local farmer preferences (MEHMOOD et al. 2013 MEHMOOD, A.; JASKANI, M.J.; AHMAD, S.; AHMAD, R. Evaluation of genetic diversity in open pollinated guava by iPBS primers. Pakistan Journal of Agricultural Sciences, Faisalabad, v.50, p.591-59, 2013. ). The main and sub groups diversity in two different districts is due to high diverse genetic makeup of guava accessions (SINGH and BAINS, 1968 SINGH, J.H.; BAINS, S.S. Genetic divergence for ginning outturn and its components in upland cotton. Indian Journal of Genetics and Plant Breeding, New Delhi, v.28, p.262-267, 1968. ). Similar results were observed by Walia and Garg (1996) WALIA, D.P.; GARG, D.K. Evaluation of genetic divergence in wheat Triticum aestivum germplasm. Indian Journal of Genetics and Plant Breeding, New Delhi, v.564, p.452-457, 1996. , Mehmood et al. (2016) MEHMOOD, A.; LUO, S.; AHMAD, N.M.; DONG, C.; MAHMOOD, T.; SAJJAD, Y.; JASKANI, M.J.; SHARP, P. Molecular variability and phylogenetic relationships of guava (Psidium guajava L.) cultivars using inter-primer binding site (iPBS) and microsatellite (SSR) markers. Genetic Resources and Crop Evolution, Dordrecht, v.63, p.1345-1361, 2016. and Dotlacil et al. (2000) DOTLACIL, L.; HERMUTH, J.; STEHNO, Z.; MANER, M. Diversity in European winter wheat landraces and obsolete cultivars. Czech Journal of Genetics and Plant Breeding, Czech Republic, v.36, p.29-36, 2000. who indicated a nonparallelization between geographic effects and genetic diversity. Unexpectedly, the accessions ‘Gola and Surahi’ showed the same genotype, which can be explained by the dissemination of seeds of the same accessions throughout these districts in the past.

The accession Bangladeshi gola (FSDS5), Lalgola (FSDS14), Larkanagola (FSDS17), Gola (SKPS26), Moti surahi (SKPS34) were one of the most important guava accessions up to now and cultivated mostly in these districts areas. Our findings also indicated that genetic diversity is connected with genetic makeup of accessions.

These results are correlated with those reported by Mehmood et al. (2016) MEHMOOD, A.; LUO, S.; AHMAD, N.M.; DONG, C.; MAHMOOD, T.; SAJJAD, Y.; JASKANI, M.J.; SHARP, P. Molecular variability and phylogenetic relationships of guava (Psidium guajava L.) cultivars using inter-primer binding site (iPBS) and microsatellite (SSR) markers. Genetic Resources and Crop Evolution, Dordrecht, v.63, p.1345-1361, 2016. .

Figure 1
Two-dimensional PCA plot based on the first two components for 31 morphological traits of 37 Pakistani guava accessions.

Figure 2
Wards linkage method of phenotypic diversity among 37 guava accessions based on morphological characters, distance linkage range is from 2% to 25%.

Figure 3
A dendrogram computed using PyElph software to cluster 37 guava accessions, the range of genetic diversity among 37 guava accessions is 1% to 50%.

Figure 4
Phenotypic fruit traits used for the selection of guava accessions. (a) pear shape (narrow neck) (b) karalla (long neck) (c) pear shape (cream skin) (d) round shape (white skin) (e) round (pink blush) (f) pear shape (rough skin) (g) dark pink flesh (h) pink flesh (i) low seeded.

Thumbnail

Table 1
List of guava accessions with phenotypic characteristics selected from districts Faisalabad (FSDS) and Sheikhupura (SKPS), Pakistan.

Thumbnail

Table 2
18 SSR primers (RISTERUCCI et al., 2005) showing amplification, polymorphism, and size among 37 guava accessions.

Conclusion

From our study, it can be concluded that wide variation in terms of morphological traits and molecular analysis exists among guava genotypes (Figure 4). Wide range of variability was observed among the genotypes with respect to different morpho-genetic characteristics.

Results suggested that the quantification of traits could help to understand the potential of germplasm in selection of potential parent for their future utilization in breeding programmes. The present study showed a high degree of variation among analyzed guava genotypes indicating that existing guava germplasms are important source of genetic diversity that can be used in the guava improvement programme.

Acknowledgments

The authors appreciate the financial support of Institute of Horticultural Sciences, University of Agriculture, Faisalabad, Pakistan and Punjab Agricultural Research Board (PRAB), for providing research funds for this study.

AHMED, B.; MANNAN, M.A.; HOSSAIN, S.A. Molecular characterization of guava (Psidium guajava L.) germplasm by RAPD analysis. International Journal of Natural Sciences, Bangladesh, v.1, p.62-67, 2011.
ANDRÉS-AGUSTÍN, J.; GONZÁLEZ-ANDRÉS F.R.; NIETO-ÁNGEL R.; BARRIENTOS-PRIEGO A.F. Morphometry of the organs of cherimoya (Annona cherimola Mill.) and analysis of fruit parameters for the characterization of cultivars, and Mexican germplasm selection. Scientia Horticulturae, Wageningen, v.4, p.337-346, 2006.
ARANGUREN, Y.; BRICENO, A.; FERMIN, G. Assessment of the variability of Venezuelan guava landraces by microsatellites. Acta Horticulturae, Leuven, v.849, p.147-154, 2010,
BRICENO, A.; ARANGUREN, Y.; FERMIN, G. Assessment of guavaderived SSR markers for the molecular characterization of Myrtaceae from different ecosystems in Venezuela. Acta Horticulturae, Leuven, v.849, p.139-146, 2010.
COSER, S.M.; DA SILVA FERREIRA, M.F.; FERREIRA, A.; MITRE, L.K.; CARVALHO, C.R.; CLARINDO, W.R. Assessment of genetic diversity in Psidium guajava L. using different approaches. Scientia Horticulturae, Wageningen, v.148, p.223-229, 2012.
DOTLACIL, L.; HERMUTH, J.; STEHNO, Z.; MANER, M. Diversity in European winter wheat landraces and obsolete cultivars. Czech Journal of Genetics and Plant Breeding, Czech Republic, v.36, p.29-36, 2000.
FRANCO, T.; HIDALGO, R. Análisis estadístico de datos de caracterización morfológica. Rome: IPGRI, 2002. (Technical Bulletin, 8)
IMRAN, H.; MUHAMMAD, S.; SAJID, A.K.; MUHAMMAD, J.J.; Zia, U. Occurrence of guava anthracnose in Punjab (Pakistan) and its integrated management. Pakistan Journal of Agricultural Sciences, Faisalabad, v.50, p.707-710, 2013.
JUNIOR, J.F.S.; BEZERRA, J.E.F.; TAVARES, J.A.; LEDERMAN, I.E.; DE MELO-NETO, M.L.; NETO, L.G. Caracterización y evaluación de germoplasma de Guayabo (Psidium guajava L.) en la región semiárida del Estado de Pernambuco, Brasil. Revista Caatinga, Mossoró, v.21, p.94-99, 2008.
KUBITZKI, K.; KALLUNKI, J.A.; DURETTO, M.; WILSON, P.G. Rutaceae. In: KUBITZKI, K. (Ed.). The families and genera of vascular plants. Berlin: Springer, 2010. v.10.
MEHMOOD, A.; JASKANI, M.J.; AHMAD, S.; AHMAD, R. Evaluation of genetic diversity in open pollinated guava by iPBS primers. Pakistan Journal of Agricultural Sciences, Faisalabad, v.50, p.591-59, 2013.
MEHMOOD, A.; JASKANI, M.J.; KHAN, I.A.; AHMAD, S.; AHMAD, R.; AHMAD, N.M.; LUO, S. 2014. Genetic diversity of Pakistani guava (Psidium guajava L.) germplasm and its implications for conservation and breeding. Scientia Horticulturae, Wageningen, v.172, p.221-232, 2014.
MEHMOOD, A.; LUO, S.; AHMAD, N.M.; DONG, C.; MAHMOOD, T.; SAJJAD, Y.; JASKANI, M.J.; SHARP, P. Molecular variability and phylogenetic relationships of guava (Psidium guajava L.) cultivars using inter-primer binding site (iPBS) and microsatellite (SSR) markers. Genetic Resources and Crop Evolution, Dordrecht, v.63, p.1345-1361, 2016.
MENZEL, C.M. Guava: an exotic fruit with potential in Queensland. Queensland Agricultural Journal, Brisbane, v.111, p. 93-98, 1985.
MURRAY, M.; THOMPSON, W.F. Rapid isolation of high molecular weight plant DNA. Nucleic Acids Research, London, v.8, p.4321-4326, 1980.
PADILLA-RAMIREZ, J.S.; GONZALEZ-GAONA, E. Collection and characterization of Mexican guava (Psidium guajava L.) germplasm. Acta Horticulturae, Leuven, v.849, p.49-54, 2010.
PAKISTAN STATISTICAL YEARBOOK. Federal bureau of statistics. Islamabad: Ministry of Economic Affairs and Statistics, Government of Pakistan, 2010.
POEHLMAN, J. M. Breeding field crops. 3rd ed. New York: Springer Publication, 1987. p.15-25.
POMMER, C.V.; MURKAMI K.R.N. Breeding guava (Psidium guajava L.). In: JAIN, S.M.; PRIYADARSHAN, P.M. (Ed.). Breeding plantation tree crops: tropical species. New York: Springer, 2009. p.83-120.
RISTERUCCI, A.M.; DUVAL, M.F.; ROHDE, W.; BILLOTTE, N. Isolation and characterization of microsatellite loci from Psidium guajava L. Molecular Ecology Notes, Oxford, v.5, p.745-748, 2005.
RITTER, E. Guava biotechnologies, genomic achievements and future needs. Acta Horticulturae, Leuven, v. 959, p. 131-140, 2012.
RODRÍGUEZ–MEDINA, N.N.; INFANTE J.V.; VELASQUEZ, B.; RIVERO, D.; MARTINEZ, F.; RISTERUCCI, A.M.; BILLOTTE, N.; BECKER, D.; RITTER, E.; ROHDE, W. 2007. Individual versus combined data set for molecular characterization of Cuban guava Psidium guajava germplasm. Acta Horticulturae, Leuven, v.849, p.163-172, 2007.
SANCHEZ-TEYER, L.F.; BARRAZA-MORALES, A.; KEB, L.; BARREDO, F.; QUIROZ-MORENO, A.; O’CONNOR-SANCHEZ, A.; PADILLA-RAMIREZ, J.S. Assessment of genetic diversity of Mexican guava germplasm using DNA molecular markers. Acta Horticulturae, Leuven, v.849, p.133-138, 2010.
SINGH, J.H.; BAINS, S.S. Genetic divergence for ginning outturn and its components in upland cotton. Indian Journal of Genetics and Plant Breeding, New Delhi, v.28, p.262-267, 1968.
THALITA, N.M.; LOURISMAR, M.A.; PETTERSON, B.L.; LEONARDA, G.N.; MARCO, A.A.B. Genetic diversity of Passiflora accessions based on morphophysiological seed descriptors. Revista Brasileira de Fruticultura, Jaboticabal, v.39, n.5, p.e-365, 2017.
UPOV. Guidelines for the conduct of tests for distinctness, homogeneity and stability. Guava (Psidium guajava L.). Geneva, 1987. p.29. (TG/110/3)
VALDÉS-INFANTE, D.; BECKER, D.; RODRÍGUEZ, N.; VELÁZQUEZ, B.; GONZÁLEZ, G.; SOURD, D.; RODRÍGUEZ, J.; RITTER, E.; ROHDE, W. Molecular characterization of Cuban accessions of guava (Psidium guajava L.), establishment of a first molecular linkage map and mapping of QTLs for vegetative characters. Journal of Genetics and Breeding, Italy, v.57, p.349-358, 2003.
VALDÉS-INFANTE, J.; RODRIGUEZ, N.N.; VELASQUEZ B.; RIVER, D.O.; MARTINEZ, F.; ESPINOSA, G.; RISTERUCCI, A.M.; BILLOTTE, N.; BECKER, D.; ROHDE, W. 2010. Simple sequence repeats SSRs for diversity characterization of guava Psidium guajava L. Acta Horticulturae, Leuven, v.849, p.155-162, 2010.
WALIA, D.P.; GARG, D.K. Evaluation of genetic divergence in wheat Triticum aestivum germplasm. Indian Journal of Genetics and Plant Breeding, New Delhi, v.564, p.452-457, 1996.

Publication Dates

Publication in this collection
2018

History

Received
18 Sept 2017
Accepted
26 Jan 2018

This is an Open-Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] AHMED, B.; MANNAN, M.A.; HOSSAIN, S.A. Molecular characterization of guava (Psidium guajava L.) germplasm by RAPD analysis. International Journal of Natural Sciences, Bangladesh, v.1, p.62-67, 2011.

[2] ANDRÉS-AGUSTÍN, J.; GONZÁLEZ-ANDRÉS F.R.; NIETO-ÁNGEL R.; BARRIENTOS-PRIEGO A.F. Morphometry of the organs of cherimoya (Annona cherimola Mill.) and analysis of fruit parameters for the characterization of cultivars, and Mexican germplasm selection. Scientia Horticulturae, Wageningen, v.4, p.337-346, 2006.

[3] ARANGUREN, Y.; BRICENO, A.; FERMIN, G. Assessment of the variability of Venezuelan guava landraces by microsatellites. Acta Horticulturae, Leuven, v.849, p.147-154, 2010,

[4] BRICENO, A.; ARANGUREN, Y.; FERMIN, G. Assessment of guavaderived SSR markers for the molecular characterization of Myrtaceae from different ecosystems in Venezuela. Acta Horticulturae, Leuven, v.849, p.139-146, 2010.

[5] COSER, S.M.; DA SILVA FERREIRA, M.F.; FERREIRA, A.; MITRE, L.K.; CARVALHO, C.R.; CLARINDO, W.R. Assessment of genetic diversity in Psidium guajava L. using different approaches. Scientia Horticulturae, Wageningen, v.148, p.223-229, 2012.

[6] DOTLACIL, L.; HERMUTH, J.; STEHNO, Z.; MANER, M. Diversity in European winter wheat landraces and obsolete cultivars. Czech Journal of Genetics and Plant Breeding, Czech Republic, v.36, p.29-36, 2000.

[7] FRANCO, T.; HIDALGO, R. Análisis estadístico de datos de caracterización morfológica. Rome: IPGRI, 2002. (Technical Bulletin, 8)

[8] IMRAN, H.; MUHAMMAD, S.; SAJID, A.K.; MUHAMMAD, J.J.; Zia, U. Occurrence of guava anthracnose in Punjab (Pakistan) and its integrated management. Pakistan Journal of Agricultural Sciences, Faisalabad, v.50, p.707-710, 2013.

[9] JUNIOR, J.F.S.; BEZERRA, J.E.F.; TAVARES, J.A.; LEDERMAN, I.E.; DE MELO-NETO, M.L.; NETO, L.G. Caracterización y evaluación de germoplasma de Guayabo (Psidium guajava L.) en la región semiárida del Estado de Pernambuco, Brasil. Revista Caatinga, Mossoró, v.21, p.94-99, 2008.

[10] KUBITZKI, K.; KALLUNKI, J.A.; DURETTO, M.; WILSON, P.G. Rutaceae. In: KUBITZKI, K. (Ed.). The families and genera of vascular plants. Berlin: Springer, 2010. v.10.

[11] MEHMOOD, A.; JASKANI, M.J.; AHMAD, S.; AHMAD, R. Evaluation of genetic diversity in open pollinated guava by iPBS primers. Pakistan Journal of Agricultural Sciences, Faisalabad, v.50, p.591-59, 2013.

[12] MEHMOOD, A.; JASKANI, M.J.; KHAN, I.A.; AHMAD, S.; AHMAD, R.; AHMAD, N.M.; LUO, S. 2014. Genetic diversity of Pakistani guava (Psidium guajava L.) germplasm and its implications for conservation and breeding. Scientia Horticulturae, Wageningen, v.172, p.221-232, 2014.

[13] MEHMOOD, A.; LUO, S.; AHMAD, N.M.; DONG, C.; MAHMOOD, T.; SAJJAD, Y.; JASKANI, M.J.; SHARP, P. Molecular variability and phylogenetic relationships of guava (Psidium guajava L.) cultivars using inter-primer binding site (iPBS) and microsatellite (SSR) markers. Genetic Resources and Crop Evolution, Dordrecht, v.63, p.1345-1361, 2016.

[14] MENZEL, C.M. Guava: an exotic fruit with potential in Queensland. Queensland Agricultural Journal, Brisbane, v.111, p. 93-98, 1985.

[15] MURRAY, M.; THOMPSON, W.F. Rapid isolation of high molecular weight plant DNA. Nucleic Acids Research, London, v.8, p.4321-4326, 1980.

[16] PADILLA-RAMIREZ, J.S.; GONZALEZ-GAONA, E. Collection and characterization of Mexican guava (Psidium guajava L.) germplasm. Acta Horticulturae, Leuven, v.849, p.49-54, 2010.

[17] PAKISTAN STATISTICAL YEARBOOK. Federal bureau of statistics. Islamabad: Ministry of Economic Affairs and Statistics, Government of Pakistan, 2010.

[18] POEHLMAN, J. M. Breeding field crops. 3rd ed. New York: Springer Publication, 1987. p.15-25.

[19] POMMER, C.V.; MURKAMI K.R.N. Breeding guava (Psidium guajava L.). In: JAIN, S.M.; PRIYADARSHAN, P.M. (Ed.). Breeding plantation tree crops: tropical species. New York: Springer, 2009. p.83-120.

[20] RISTERUCCI, A.M.; DUVAL, M.F.; ROHDE, W.; BILLOTTE, N. Isolation and characterization of microsatellite loci from Psidium guajava L. Molecular Ecology Notes, Oxford, v.5, p.745-748, 2005.

[21] RITTER, E. Guava biotechnologies, genomic achievements and future needs. Acta Horticulturae, Leuven, v. 959, p. 131-140, 2012.

[22] RODRÍGUEZ–MEDINA, N.N.; INFANTE J.V.; VELASQUEZ, B.; RIVERO, D.; MARTINEZ, F.; RISTERUCCI, A.M.; BILLOTTE, N.; BECKER, D.; RITTER, E.; ROHDE, W. 2007. Individual versus combined data set for molecular characterization of Cuban guava Psidium guajava germplasm. Acta Horticulturae, Leuven, v.849, p.163-172, 2007.

[23] SANCHEZ-TEYER, L.F.; BARRAZA-MORALES, A.; KEB, L.; BARREDO, F.; QUIROZ-MORENO, A.; O’CONNOR-SANCHEZ, A.; PADILLA-RAMIREZ, J.S. Assessment of genetic diversity of Mexican guava germplasm using DNA molecular markers. Acta Horticulturae, Leuven, v.849, p.133-138, 2010.

[24] SINGH, J.H.; BAINS, S.S. Genetic divergence for ginning outturn and its components in upland cotton. Indian Journal of Genetics and Plant Breeding, New Delhi, v.28, p.262-267, 1968.

[25] THALITA, N.M.; LOURISMAR, M.A.; PETTERSON, B.L.; LEONARDA, G.N.; MARCO, A.A.B. Genetic diversity of Passiflora accessions based on morphophysiological seed descriptors. Revista Brasileira de Fruticultura, Jaboticabal, v.39, n.5, p.e-365, 2017.

[26] UPOV. Guidelines for the conduct of tests for distinctness, homogeneity and stability. Guava (Psidium guajava L.). Geneva, 1987. p.29. (TG/110/3)

[27] VALDÉS-INFANTE, D.; BECKER, D.; RODRÍGUEZ, N.; VELÁZQUEZ, B.; GONZÁLEZ, G.; SOURD, D.; RODRÍGUEZ, J.; RITTER, E.; ROHDE, W. Molecular characterization of Cuban accessions of guava (Psidium guajava L.), establishment of a first molecular linkage map and mapping of QTLs for vegetative characters. Journal of Genetics and Breeding, Italy, v.57, p.349-358, 2003.

[28] VALDÉS-INFANTE, J.; RODRIGUEZ, N.N.; VELASQUEZ B.; RIVER, D.O.; MARTINEZ, F.; ESPINOSA, G.; RISTERUCCI, A.M.; BILLOTTE, N.; BECKER, D.; ROHDE, W. 2010. Simple sequence repeats SSRs for diversity characterization of guava Psidium guajava L. Acta Horticulturae, Leuven, v.849, p.155-162, 2010.

[29] WALIA, D.P.; GARG, D.K. Evaluation of genetic divergence in wheat Triticum aestivum germplasm. Indian Journal of Genetics and Plant Breeding, New Delhi, v.564, p.452-457, 1996.

code	Accession name	Botanical name	Native	Phenotypic characteristics
FSDS₁	Gola	P. guajava	Faisalabad	Round (medium size)
FSDS₂	Surahi	P. guajava	Faisalabad	Pear shape (medium size)
FSDS₃	Rough gola	P. guajava	Faisalabad	Round (grooved skin)
FSDS₄	Motagola	P. guajava	Faisalabad	Round (large size)
FSDS₅	Bangladeshi gola	P. guajava	Faisalabad	Round (Extra-large size)
FSDS₆	Lalgola	P. cattleianum	Faisalabad	Round (pink flesh)
FSDS₇	Surahi	P. guajava	Faisalabad	Pear shape (medium size)
FSDS₈	Khatta	P. guajava	Faisalabad	Round (sour taste)
FSDS₉	Surahi	P. guajava	Faisalabad	Pear shape (small size)
FSDS₁₀	Gola	P. guajava	Faisalabad	Round (small size)
FSDS₁₁	Allah Abadi gola	P. guajava	Faisalabad	Round (medium size)
FSDS₁₂	Lalgola	P. cattleianum	Faisalabad	Round (pink flesh)
FSDS₁₃	Karalla	P. guajava	Faisalabad	Pear shape (long neck)
FSDS₁₄	Lalgola	P. cattleianum	Faisalabad	Round (pink flesh)
FSDS₁₅	Gola	P. guajava	Faisalabad	Round (medium size)
FSDS₁₆	Sadabahar gola	P. guajava	Faisalabad	Round (medium size)
FSDS₁₇	Larkanagola	P. guajava	Faisalabad	Round (medium size)
SKPS₁₈	Gola	P. guajava	Sheikhupura	Round (medium size)
SKPS₁₉	Mota gola	P. guajava	Sheikhupura	Round (medium size)
SKPS₂₀	Surahi	P. guajava	Sheikhupura	Pear shape (medium size)
SKPS₂₁	Chota gola	P. guajava	Sheikhupura	Round (small size)
SKPS₂₂	Gola	P. guajava	Sheikhupura	Round (medium size)
SKPS₂₃	Surahi	P. guajava	Sheikhupura	Pear shape (medium size)
SKPS₂₄	Gola	P. guajava	Sheikhupura	Round (medium size)
SKPS₂₅	Surahi	P. guajava	Sheikhupura	Pear shape (medium size)
SKPS₂₆	Gola	P. guajava	Sheikhupura	Round (medium size)
SKPS₂₇	Mota gola	P. guajava	Sheikhupura	Round (large size)
SKPS₂₈	Lalgola	P. cattleianum	Sheikhupura	Round (pink flesh)
SKPS₂₉	Choti surahi	P. guajava	Sheikhupura	Pear shape (small size)
SKPS₃₀	Larkana gola	P. guajava	Sheikhupura	Round (medium size)
SKPS₃₁	Desi gola	P. guajava	Sheikhupura	Round (small size)
SKPS₃₂	Gola	P. guajava	Sheikhupura	Round (medium size)
SKPS₃₃	Mota gola	P. guajava	Sheikhupura	Round (large size)
SKPS₃₄	Moti surahi	P. guajava	Sheikhupura	Pear shape (large size)
SKPS₃₅	Gola	P. guajava	Sheikhupura	Round (medium size)
SKPS₃₆	Sadabahar gola	P. guajava	Sheikhupura	Round (medium size)
SKPS₃₇	Sadabahar gola	P. guajava	Sheikhupura	Round (medium size)

Sr. No.	Primer	Forward Sequence	Reverse sequence	Ta (°C)	No. of Alleles	Allele size range
1	mPgCIR02	AGTGAACGACTGAAGACC	ATTACACATTCAGCCACTT	55	5	232-260
2	mPgCIR03	TTGTGGCTTGATTTCC	TCGTTTAGAGGACATTTCT	55	2	202-220
3	mPgCIR05	GCCTTTGAACCACATC	TCAATACGAGAGGCAATA	55	5	230-295
4	mPgCIR07	ATGGAGGTAGGTTGATG	CGTAGTAATCGAAGAAATG	55	6	160-170
5	mPgCIR08	ACTTTCGGTCTCAACAAG	AGGCTTCCTACAAAAGTG	55	5	215-235
6	mPgCIR09	GCGTGTCGTATTGTTTC	ATTTTCTTCTGCCTTGTC	55	4	160-185
7	mPgCIR10	GTTGGCTCTTATTTTGGT	GCCCCATATCTAGGAAG	55	4	265-290
8	mPgCIR11	TGAAAGACAACAAACGAG	TTACACCCACCTAAATAAGA	55	5	298-320
9	mPgCIR14	TAAACACAACAAGGGTCA	CAGTTTTCATATCGTCCTC	55	5	190-200
10	mPgCIR15	TCTAATCCCCTGAGTTTC	CCGATCATCTCTTTCTTT	55	5	240-270
11	mPgCIR16	AATACCAGCAACACCAA	CATCCGTCTCTAAACCTC	55	5	270-300
12	mPgCIR17	CCTTTCGTCATATTCACTT	CATTGGATGGTTGACAT	55	3	150-240
13	mPgCIR18	TAAGCTGCATGTGTGC	ATGGCTTTGGATGAAA	55	5	180-200
14	mPgCIR19	AAAATCCTGAAGACGAAC	TATCAGAGGCTTGCATTA	55	3	265-280
15	mPgCIR20	TATACCACACGCTGAAAC	TTCCCCATAAACATCTCT	55	6	275-300
16	mPgCIR21	TGCCCTTCTAAGTATAACAG	AGCTACAAACCTTCCTAAA	55	5	250-285
17	mPgCIR22	CATAAGGACATTTGAGGAA	AATAAGAAAGCGAGCAGA	55	5	200-278
18	mPgCIR25	GACAATCCAATCTCACTTT	TGTGTCAAGCATACCTTC	55	6	170-200

Brasil