Sage Journals: Discover world-class research

Abstract

This study assessed morphological and genetic diversity in twelve Berberis F₂ populations. Seeds were collected from selected F₁ hybrids resulting from crosses between Berberis integerrima, B. crataegina, and ‘Zereshk Bidaneh’-a commercial seedless barberry cultivar. Initial evaluations compared seed germination and seedling survival on three substrates: perlite, cocopeat, and peat moss. Germination rates varied widely among F₂ populations, ranging from 17% to 95.48%. A 1:1 mixture of cocopeat and perlite significantly enhanced germination. Twelve morphological and vegetative traits were subsequently measured, revealing substantial phenotypic variability across F₂ populations. Correlation analyses identified strong positive associations among key traits such as leaf number, plant height, and leaf morphology characters. Factorial analysis indicated that the first two factors explained 35.5% of the total variance, primarily differentiating populations based on leaf pigmentation and leaf-spine architecture. Heatmap clustering grouped the F₂ genotypes into six distinct phenotypic clusters. Notably, traits such as leaf margin spine (CV = 33.89%) and leaf pigmentation (CV > 43%) exhibited high coefficients of variation, suggesting the potential for transgressive segregation and providing a wide basis for selection. These findings establish a robust framework for early-stage selection in barberry improvement programs.

Keywords

genetic diversity hybridization morphological traits seedling survival

Get full access to this article

View all access options for this article.

References

Hsieh

C-L

C-C

Huang

Y-L

, et al. Mahonia vs. Berberis unloaded: generic delimitation and infrafamilial classification of Berberidaceae based on plastid phylogenomics. Front Plant Sci 2021; 12: 720171–720171.

Rezaei

Sarkhosh

. Barberry (Berberis spp.) domestication and breeding. In: Al-Khayri

Jain

Penna

(eds) Biodiversity and genetic improvement of medicinal and aromatic plants I. Advances in Plant Breeding Strategies. Cham, Switzerland: Springer, 2025, pp.23–67. 10.1007/978-3-031-81846-2_2

Ghahramanlu

Rezaei

Heidari

, et al. Species survey of Iranian barberry genotypes using ITS2 sequences and basic local alignment search tools. Erwerbs-Obstbau 2023; 65: 2491–2499.

Isakova

Vinokurov

Danilova

, et al. Study of adaptive states and variability of phenological development of introduced woody plants of the genus Berberis L. In the conditions of the Altai botanical garden. Fundamental Exp Biol 2025; 11930: 115–127.

Brand

Lehrer

Lubell

. Fecundity of Japanese barberry (Berberis thunbergii) cultivars and their ability to invade a deciduous woodland. Invasive Plant Sci Manag 2012; 5: 464–476.

Salehi

Selamoglu

Sener

, et al. Berberis plants-drifting from farm to food applications, phytotherapy, and phytopharmacology. Foods 2019; 8. 10.3390/foods8100522

Yildiz

Ercisli

Sengul

, et al. Some physicochemical characteristics, bioactive content and antioxidant characteristics of non-sprayed barberry (Berberis vulgaris L.) fruits from Turkey. Erwerbs-Obstbau 2014; 56: 123–129.

Chacón-Fuentes

Burgos-Díaz

Opazo-Navarrete

, et al. Berberine and palmatine distribution across plant organs in Berberis darwinii: basis for selecting superior-producing accessions. Molecules 2025; 30: 1849. https://www.mdpi.com/1420-3049/30/8/1849

Imenshahidi

Hosseinzadeh

. Berberine and barberry (Berberis vulgaris): a clinical review. Phytother Res 2019; 33: 504–523.

10.

Safari-Khozani

Rezaei

Tunç

, et al. Biochemical, antioxidant activity, and phenological diversity among Berberis progenies in the F₁ population. Sci Rep 2025; 15: 24967.

11.

Awang

Shaharom

Mohamad

, et al. Chemical and physical characteristics of cocopeat-based Media mixtures and their effects on the growth and development of Celosia cristata. Am J Agri Biol Sci 2009; 4. 10.3844/ajabssp.2009.63.71

12.

Khalaj

Amiri

Sindhu

. Response of different growing media on the growth and yield of gerbera in hydroponic open system. Indian J Horticulture 2011; 68: 583–586. https://journal.iahs.org.in/index.php/ijh/article/view/1961

13.

Begna

. Conventional breeding methods widely used to improve self-pollinated crops. Int J Res 2021; 7: 1–16.

14.

Safari

Rezaei

. Assessing genetic diversity of Berberis genotypes selected from an F₁ population using molecular markers. J Berry Res 2023; 13: 343–353.

15.

Rezaei

Balandary

. Effects of gibberellic acid (Ga3), stratification and acid scarification on the seed germination of three Iranian barberry genotypes. Seed Res J Persian 2012; 2: 11–18. https://www.sid.ir/en/journal/ViewPaper.aspx?ID=353823

16.

UPOV: Berberis L. BERBERIS, épine-vinette directeurs, principes de l’examen, pour la conduite de la distinction, de l’homogénéité de la stabilité, eT Union Internationale Pour La Protection Des Obtentions Végétales. 2022.

17.

Rezaei

Balandary

. Study of seed set in crossing among seedless barberry and wild type barberry genotypes. Iranian J Hortic Sci 2015; 46: 323–331.

18.

Hassanpour

Alizadeh

. Evaluation of phenolic compound, antioxidant activities and antioxidant enzymes of barberry genotypes in Iran. Sci Hortic 2016; 200: 125–130.

19.

Heidary

Marashi

Farsi

, et al. Assessment of genetic structure and variation of native Berberis populations of khorasan provinces (Iran) using AFLP markers versus morphological markers. Iranian J Biotechnol 2009; 7: 101–107. https://www.ijbiotech.com/article_7087_b77f0f518cc554f12100ca6e7167685f.pdf

20.

Heidari

Marashi

Mollafilabi

, et al. Cytogenetic and Pollination Studies in Seedless Barberry (Berberidaceae) and its Relative Species in Eastern Iran. 28th International Horticultural Congress. 2010.

Morphological diversity and early growth performance of F 2 populations of barberry ( Berberis spp.) from interspecific hybridization

Abstract

Keywords

Get full access to this article

References