Authentication of Apis Cerana and Apis Mellifera Derived Honey Using Major Royal Jelly Protein 2 Gene and Spectroscopy



Abstract Views
288

Downloads
260

Citations

Share

##plugins.themes.bootstrap3.article.sidebar##

Submitted Dec 17, 2022
Published Jan 30, 2023
10.24018/ejfood.2023.5.1.624

Abstract viewed = 288 times

Table of Contents

##plugins.themes.bootstrap3.article.main##

Honey, as a natural health product, encounter great compositional influence by its entomological, botanical and geographical origin. In Bangladesh, apiculture relies on the honey production by mostly the European honeybee, Apis mellifera. However, the Asian honeybee Apis cerana honey typically costs three times as much as honey from A. mellifera in honey market due to the production limit, variation in nutrient composition, being prone to adulteration by mislabeling or incorporation of two honey. A. mellifera honey may be mislabeled as A. cerana honey or mixed with A. cerana honey by dishonest businesses and beekeepers who are motivated by substantial earnings. The current study used the MRJP2 (Major Royal Jelly Protein 2) gene and spectroscopic analysis to differentiate honey from A. mellifera and A. cerana. Primers for two different species were designed. A. cerana and A. mellifera exhibited amplification products of 212 and 560 bp, respectively. Duplex PCR was able to identify the presence of as little as 1% A. mellifera honey in the mixture. A. mellifera and A. cerana originated honey was differentiated using MRJP2 gene and UV-VIS spectroscopy. The resulted banding pattern can be used to identify adulterated honey. UV-VIS spectroscopy has been used to determine the concentration of DNA at different wavelength for standardizing the corresponding honey types. Amplifications MRJP2 gene fragments in gel electrophoresis and responsiveness in screening for two honey types with their probable admixtures provided an effective tool for discriminating the honey types. DNA Spectrophotometric Spectrum analysis in different wavelengths and ratios also provided a clear-cut discrimination protocol of these two honey types. The findings of these two methods can be used efficiently apply towards authentication of the honey originated by A. mellifera and A. cerana in the honey market of Bangladesh.

Keywords: honey authentication honeybee mrjp2 gene social insects

References

  1. Aries E, Burton J, Carrasco L, De Rudder O, Maquet A. Scientific support to the implementation of a coordinated control plan with a view to establishing the prevalence of fraudulent practices in the marketing of honey. European Commission, Belgium. 2016; p. 38.
     Google Scholar
  2. Wu L, Du B, Vander Heyden Y, Chen L, Zhao L, Wang M, Xue X. Recent advancements in detecting sugar-based adulterants in honey–A challenge. TrAC Trends in Analytical Chemistry. 2017 Jan 1; 86:25–38.
     Google Scholar
  3. Oroian M, Ropciuc S, Paduret S, Todosi E. Rheological analysis of honeydew honey adulterated with glucose, fructose, inverted sugar, hydrolysed inulin syrup and malt wort. LWT. 2018 Sep 1; 95:1–8.
     Google Scholar
  4. Soares S, Grazina L, Costa J, Amaral JS, Oliveira MB, Mafra I. Botanical authentication of lavender (Lavandula spp.) honey by a novel DNA-barcoding approach coupled to high resolution melting analysis. Food Control. 2018a Apr 1; 86:367–73.
     Google Scholar
  5. Moniruzzaman M, Rahman MS. Prospects of beekeeping in Bangladesh. Journal of the Bangladesh Agricultural University. 2009;7(452-2016-35479).
     Google Scholar
  6. Won SR, Li CY, Kim JW, Rhee HI. Immunological characterization of honey major protein and its application. Food Chemistry. 2009 Apr 15;113(4):1334–8.
     Google Scholar
  7. Soares S, Amaral JS, Oliveira MB, Mafra I. A comprehensive review on the main honey authentication issues: Production and origin. Comprehensive Reviews in Food Science and Food Safety. 2017 Sep;16(5):1072–100.
     Google Scholar
  8. Ramón-Sierra JM, Ruiz-Ruiz JC, de la Luz Ortiz-Vázquez E. Electrophoresis characterization of protein as a method to establish the entomological origin of stingless bee honeys. Food Chemistry. 2015 Sep 15; 183:43–8.
     Google Scholar
  9. Kek SP, Chin NL, Tan SW, Yusof YA, Chua LS. Molecular identification of honey entomological origin based on bee mitochondrial 16S rRNA and COI gene sequences. Food Control. 2017 Aug 1; 78:150–9.
     Google Scholar
  10. Prosser SW, Hebert PD. Rapid identification of the botanical and entomological sources of honey using DNA metabarcoding. Food Chemistry. 2017 Jan 1; 214:183–91.
     Google Scholar
  11. Soares S, Grazina L, Mafra I, Costa J, Pinto MA, Duc HP, Oliveira MB, Amaral JS. Novel diagnostic tools for Asian (Apis cerana) and European (Apis mellifera) honey authentication. Food Research International. 2018b Mar 1; 105:686–93.
     Google Scholar
  12. Amaral J, Meira L, Oliveira MB, Mafra I. Advances in authenticity testing for meat speciation. In Advances in food authenticity testing 2016 Jan 1 (pp. 369-414). Woodhead Publishing.
     Google Scholar
  13. Amaral JS, Santos CG, Melo VS, Costa J, Oliveira MB, Mafra I. Identification of duck, partridge, pheasant, quail, chicken and turkey meats by species-specific PCR assays to assess the authenticity of traditional game meat Alheira sausages. Food Control. 2015 Jan 1; 47:190–5.
     Google Scholar
  14. Fernandes TJ, Costa J, Oliveira MB, Mafra I. DNA barcoding coupled to HRM analysis as a new and simple tool for the authentication of Gadidae fish species. Food Chemistry. 2017 Sep 1; 230:49–57.
     Google Scholar
  15. Utzeri VJ, Ribani A, Fontanesi L. Authentication of honey based on a DNA method to differentiate Apis mellifera subspecies: Application to Sicilian honeybee (A. m. siciliana) and Iberian honey bee (A. m. iberiensis) honeys. Food Control. 2018 Sep 1; 91:294–301.
     Google Scholar
  16. Clark W, Christopher K. An Introduction to DNA: Spectrophotometry, degradation, and the ‘Frankengel’experiment. Tested studies for laboratory teaching; 2000.
     Google Scholar