Palynological, Protein, and Phenolic Profiling of Bee Pollen from Mersin: An Investigation

Duygu Nur ÇOBANOĞLU

doi:10.5281/zenodo.11305923

Yazarlar

Duygu Nur ÇOBANOĞLU Bingöl University, Department of Crop and Animal Production, Vocational School of Food, Agriculture and Livestock, Bingöl https://orcid.org/0000-0002-8583-8114

DOI:

https://doi.org/10.5281/zenodo.11305923

Anahtar Kelimeler:

Bee pollen, LC-MS/MS, protein, phenolic, palynological, Mersin

Özet

Due to bee pollen's exceptional nutritional profile and unique phenolic composition, it has received significant attention recently. The aim of this study was to investigate the botanical origin, protein content, and phenolic composition of the eight bee pollen samples (BP01–BP08) from different districts of Mersin city, Türkiye. According to palynological analysis, pollen grains of 51 taxa belonging to 25 families were determined. BP01 and BP07 were bifloral, and the other samples were multifloral. Pollen belonging to the genera Ceratonia sp., Helianthemum sp. and Olea sp. were predominant in the samples. The protein content values ranged from 23.1±1.23–28.1±1.49 g/100g. The presence of 23 phenolic compounds was investigated in bee pollen samples by liquid chromatography-tandem mass spectrometry (LC-MS/MS), and 12 of them were detected. Taxifolin, caffeic acid, quercetin, oleuropein, and kaempferol were determined to be the most abundant phenolic components, respectively. The bee pollen sample with the low protein content (BP03) had the highest phenolic composition. Furthermore, protein content and phenolic composition showed significant variability based on geographical origin.

Referanslar

Adaškevičiūtė, V., Kaškonienė, V., Barčauskaitė, K., Kaškonas, P., Maruška, A., 2022. The Impact of fermentation on bee pollen polyphenolic compounds composition. Antioxidants, 11(4): 645.

Alimoglu, G., Guzelmeric, E., Yuksel, P.I., Celik, C., Deniz, I., Yesilada, E., 2021. Monofloral and polyfloral bee pollens: Comparative evaluation of their phenolics and bioactivity profiles. Lwt, 142(5): 110973.

Al-Kahtani, S.N., 2017. Fatty acids and B vitamins contents in honey bee collected pollen in relation to botanical origin. Sicientific Journal of King Fasal University, 18(2):41–48.

Almeida-Muradian, L.B., Pamplona, L.C., Coimbra, S., Barth, O.M., 2005. Chemical composition and botanical evaluation of dried bee pollen pellets. Journal of Food Composition and Analysis, 18 (1): 105–111.

Altunatmaz, S.S., Tarhan, D., Aksu, F., Barutçu, U.B., Or, M.E., 2017. Mineral element and heavy metal (Cadmium, lead and arsenic) levels of bee pollen in Turkey. Food Science and Technology, 37: 136–141.

Alvarez-Suarez, J.M., 2017. Bee products - chemical and biological properties. The dried chemicals. Products - Chemical and Biological Properties, Springer Cham, Germany, p. 1–306.

Ares, A.M., Valverde, S., Bernal, J.L., Nozal, M.J., Bernal, J., 2018. Extraction and determination of bioactive compounds from bee pollen. Journal of Pharmaceutical and Biomedical Analysis, 147: 110–124.

Aylanc, V., Falcão, S.I., Ertosun, S., Vilas-Boas, M., 2021. From the hive to the table: Nutrition value, digestibility and bioavailability of the dietary phytochemicals present in the bee pollen and bee bread. Trends in Food Science and Technology, 109: 464–481.

Baky, M.H., Abouelela, M.B., Wang, K., Farag, M.A., 2023. Bee pollen and bread as a super-food: a comparative review of their metabolome composition and quality assessment in the context of best recovery conditions. Molecules, 28(2): 715.

Barth, O.M., Freitas, A.S., Oliveira, É.S., Silva, R.A., Maester, F.M., Andrella, R.R. S., Cardozo, G.M.B.Q., 2010. Evaluation of the botanical origin of commercial dry bee pollen load batches using pollen analysis: A proposal for technical standardization. Anais Da Academia Brasileira de Ciencias, 82(4): 893–902.

Bridi, R., Echeverría, J., Larena, A., Nuñez Pizarro, P., Atala, E., De Camargo, A.C., Oh, W.Y., Shahidi, F., Garcia, O., Ah-Hen, K.S., Montenegro, G., 2022. Honeybee pollen from southern chile: phenolic profile, antioxidant capacity, bioaccessibility, and ınhibition of DNA Damage. Frontiers in Pharmacology, 13:1–12.

Çelik, S., Kutlu, N., Gerçek, Y.C., Bayram, S., Pandiselvam, R., Bayram, N.E., 2022. Optimization of ultrasonic extraction of nutraceutical and pharmaceutical compounds from bee pollen with deep eutectic solvents using response surface methodology. Foods, 11:3652.

Çobanoğlu, D.N., 2024. Assessing monofloral bee pollens from Türkiye: Palynological verification, phenolic profile, and antioxidant activity. Journal of Food Science, 89: 1711–1726.

Çobanoğlu, D.N., Kizilpinar Temizer, İ., Candan, E.D., Yolcu, U., Güder, A., 2023a. Evaluation of the nutritional value of bee pollen by palynological, antioxidant, antimicrobial, and elemental characteristics. European Food Research and Technology, 249: 307–325.

Çobanoğlu, D.N., Şeker, M.E., Temizer, İ.K., Erdoğan, A., 2023b. Investigation of botanical origin, phenolic compounds, carotenoids, and antioxidant properties of monofloral and multifloral bee bread. Chemistry & Biodiversity, 20: e202201124.

De-Melo, A.A.M., Estevinho, M.L.M.F., Sattler, J.A.G., Souza, B.R., Freitas, A. da S., Barth, O.M., Almeida-Muradian, L.B., 2016. Effect of processing conditions on characteristics of dehydrated bee-pollen and correlation between quality parameters. Lwt, 65: 808–815.

De Souza, R.R., de Abreu, V.H.R., de Novais, J.S., 2019. Melissopalynology in Brazil: a map of pollen types and published productions between 2005 and 2017. Palynology, 43: 690–700.

Dimou, M., Tananaki, C., Liolios, V., Thrasyvoulou, A., 2014. Pollen foraging by honey bees (Apis mellifera L.) in Greece: Botanical and geographical origin. Journal of Apicultural Science, 58: 11–23.

Dulger Altiner, D., Sandikci Altunatmaz, S., Sabuncu, M., Aksu, F., Sahan, Y., 2020. In-vitro bioaccessibility of antioxidant properties of bee pollen in Turkey. Food Science and Technology, 41: 133–141.

Estevinho, L.M., Rodrigues, S., Pereira, A.P., Feás, X., 2012. Portuguese bee pollen: Palynological study, nutritional and microbiological evaluation. International Journal of Food Science and Technology, 47: 429–435.

Çobanoğlu, D.N., Felek, İ., Dündar, O., 2021. Palynological, Antioxidant and Physicochemical Properties of Pollen Loads from Eastern Anatolia. Bee Studies, 13: 31–38.

Gercek, Y.C., Celik, S., Bayram, A.S., 2021. Screening of plant pollen sources, polyphenolic compounds, fatty acids and antioxidant/antimicrobial activity from bee pollen. Molecules, 27;117.

Giovanetti, M., 2018. Do bees like olive? A preliminary analysis of honey bee behaviour on flowers of the wind-pollinated species Olea europaea. Acta Horticulturae, 1199: 121–126.

Görhan, K., 2021. Mersin merkez ilçelerinin (Akdeniz, Toroslar, Yenişehir, Mezitli) arı bitkileri üzerine bir araştırma. MAS Journal of Applied Sciences, 8:518–523.

Halbritter, H., Ulrich, S., Grímsson, F., Weber, M., Zetter, R., Hesse, M., Buchner, R., Svojtka, M., Frosch-Radivo, A. 2018. Illustrated pollen terminology. Springer Nature, Cham, Germany, p1-483.

Hsu, P.S., Wu, T.H., Huang, M.Y., Wang, D.Y., Wu, M.C., 2021. Nutritive value of 11 bee pollen samples from major floral sources in taiwan. Foods, 10: 1–15.

Karkar, B., Şahin, S., Güneş, M.E., 2018. Antioxidative effect of turkish chestnut bee pollen on dna oxidation system and ıts phenolic compounds. Gida / The Journal of Food, 43: 34–42.

Kıvanç, M., Yapıcı, E., 2015. Kefir as a Probiotic Dairy Beverage: Determination Lactic Acid Bacteria and Yeast. ETP International Journal of Food Engineering, 1:55–60.

Komosinska-Vassev, K., Olczyk, P., Kafmierczak, J., Mencner, L., Olczyk, K., 2015. Bee pollen: chemical composition and therapeutic application. Evidence-Based Complementary and Alternative Medicine, 2015: 1-6.

Kostić, A.T., Barać, M.B., Stanojević, S.P., Milojković-Opsenica, D.M., Tešić, Ž.L., Šikoparija, B., Radišić, P., Prentović, M., Pešić, M.B., 2015. Physicochemical composition and techno-functional properties of bee pollen collected in Serbia. Lwt, 62: 301–309.

Küçükaydın, S., Tel-Çayan, G., Çayan, F., Taş-Küçükaydın, M., Eroğlu, B., Duru, M.E., Öztürk, M., 2023. Characterization of Turkish Astragalus honeys according to their phenolic profiles and biological activities with a chemometric approach. Food Bioscience, 53(2): 102507.

Li, Q.Q., Wang, K., Marcucci, M.C., Sawaya, A.C.H.F., Hu, L., Xue, X.F., Wu, L.M., Hu, F.L., 2018. Nutrient-rich bee pollen: A treasure trove of active natural metabolites. Journal of Functional Foods, 49: 472–484.

Liolios, V., Tananaki, C., Dimou, M., Kanelis, D., Goras, G., Karazafiris, E., Thrasyvoulou, A., 2015. Ranking pollen from bee plants according to their protein contribution to honey bees. Journal of Apicultural Research, 54(5): 582–592.

Maha, S., Haddad, N., 2012. Utılızatıon of forest bıodıversıty: rewards of ceratonıa sılıqua l. for apıs mellıfera, Uludag Bee Journal, 12(2):62–67.

Mărgăoan, R., Özkök, A., Keskin, Ş., Mayda, N., Urcan, A.C., Cornea-Cipcigan, M., 2021. Bee collected pollen as a value-added product rich in bioactive compounds and unsaturated fatty acids: A comparative study from Turkey and Romania, Lwt,149: 111925.

Mayda, N., Özkök, A., Ecem Bayram, N., Gerçek, Y.C., Sorkun, K., 2020. Bee bread and bee pollen of different plant sources: determination of phenolic content, antioxidant activity, fatty acid and element profiles. Journal of Food Measurement and Characterization, 14 (4): 1795–1809.

Mutlu, C., Erbas, M., 2023. Turkish bee pollen: Composition, regional discrimination and polyphenol bioaccessibility. Food Bioscience, 53: 102805.

Oroian, M., Dranca, F., Ursachi, F., 2022. Characterization of Romanian Bee Pollen—An Important Nutritional Source. Foods, 11(17): 2633.

Rocchetti, G., Castiglioni, S., Maldarizzi, G., Carloni, P., Lucini, L., 2019. UHPLC-ESI-QTOF-MS phenolic profiling and antioxidant capacity of bee pollen from different botanical origin. International Journal of Food Science & Technology, 54: 335–346.

Şahin, H., Kemal, M., 2020. Antioxidant capacity of a bee pollen sample obtained from Giresun, Turkey. Journal of Apitherapy and Nature, 2: 46–51.

Silici, S., Gökceoglu, M., 2007. Pollen analysis of honeys from Mediterranean region of Anatolia. Grana, 46: 57–64.

Somerville, D.C., 2001. Nutritional Value of Bee Collected Pollens. Rural Industries Research and Development Corporation, 1–166.

Sultana, S., Foster, K., Lim, L.Y., Hammer, K., Locher, C., 2022. A Review of the Phytochemistry and Bioactivity of Clover Honeys (Trifolium spp.). Foods, 11: 1–17.

Taha, E.K.A., Al-Kahtani, S., Taha, R., 2019. Protein content and amino acids composition of bee-pollens from major floral sources in Al-Ahsa, eastern Saudi Arabia. Saudi Journal of Biological Sciences, 26: 232–237.

Temizer, İlginç Kızılpınar, 2023. Elemental composition and evaluation of noncarcinogenic risks of bee pollen from different Turkish areas. Integrated Environmental Assessment and Management,00: 1-11:

Temizer, İlginc Kizilpinar, 2023. Diversity in bee pollen from three phytogeographical regions in Turkey. Grana, 62: 331–341.

Yang, K., Wu, D., Ye, X., Liu, D., Chen, J., Sun, P., 2013. Characterization of chemical composition of bee pollen in China. Journal Of Agricultural And Food Chemistry, 61: 708–718.

Palynological, Protein, and Phenolic Profiling of Bee Pollen from Mersin: An Investigation

Yazarlar

DOI:

Anahtar Kelimeler:

Özet

Referanslar

İndir

Yayınlanmış

Nasıl Atıf Yapılır

Sayı

Bölüm

Lisans

Makale Gönder

Dil