دورية أكاديمية
Phytochemical profiling of red raspberry (Rubus idaeus L.) honey and investigation of compounds related to its pollen occurrence.
| العنوان: | Phytochemical profiling of red raspberry (Rubus idaeus L.) honey and investigation of compounds related to its pollen occurrence. |
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| المؤلفون: | Leoni V; Department of Agricultural and Environmental Sciences-Production, Landscape, Agroenergy (DISAA), University of Milan, Milan, Italy.; Centre of Applied Studies for the Sustainable Management and Protection of Mountain Areas (CRC Ge.S.Di.Mont.), University of Milan, Milan, Italy., Panseri S; Centre of Applied Studies for the Sustainable Management and Protection of Mountain Areas (CRC Ge.S.Di.Mont.), University of Milan, Milan, Italy.; Department of Veterinary Medicine and Animal Sciences (DIVAS), University of Milan, Lodi, Italy., Giupponi L; Department of Agricultural and Environmental Sciences-Production, Landscape, Agroenergy (DISAA), University of Milan, Milan, Italy.; Centre of Applied Studies for the Sustainable Management and Protection of Mountain Areas (CRC Ge.S.Di.Mont.), University of Milan, Milan, Italy., Pavlovic R; Proteomics and Metabolomics Facility (PROMEFA), San Raffaele Scientific Institute, Milan, Italy., Gianoncelli C; Fondazione Fojanini Di Studi Superiori, Sondrio, Italy., Coatti G; Department of Agricultural and Environmental Sciences-Production, Landscape, Agroenergy (DISAA), University of Milan, Milan, Italy.; Centre of Applied Studies for the Sustainable Management and Protection of Mountain Areas (CRC Ge.S.Di.Mont.), University of Milan, Milan, Italy., Beretta G; Department of Environmental Science and Policy (ESP), University of Milan, Milan, Italy., Giorgi A; Department of Agricultural and Environmental Sciences-Production, Landscape, Agroenergy (DISAA), University of Milan, Milan, Italy.; Centre of Applied Studies for the Sustainable Management and Protection of Mountain Areas (CRC Ge.S.Di.Mont.), University of Milan, Milan, Italy. |
| المصدر: | Journal of the science of food and agriculture [J Sci Food Agric] 2024 Jul; Vol. 104 (9), pp. 5391-5406. Date of Electronic Publication: 2024 Feb 22. |
| نوع المنشور: | Journal Article |
| اللغة: | English |
| بيانات الدورية: | Publisher: John Wiley & Sons Country of Publication: England NLM ID: 0376334 Publication Model: Print-Electronic Cited Medium: Internet ISSN: 1097-0010 (Electronic) Linking ISSN: 00225142 NLM ISO Abbreviation: J Sci Food Agric Subsets: MEDLINE |
| أسماء مطبوعة: | Publication: <2005-> : Chichester, West Sussex : John Wiley & Sons Original Publication: London, Society of Chemical Industry. |
| مواضيع طبية MeSH: | Rubus*/chemistry , Pollen*/chemistry , Honey*/analysis , Phytochemicals*/analysis , Phytochemicals*/chemistry , Gas Chromatography-Mass Spectrometry*, Chromatography, High Pressure Liquid ; Solid Phase Microextraction |
| مستخلص: | Background: Red raspberry (Rubus idaeus L.) is an important nectar source for honey production in some specific habitats as well as an important crop, so the definition of the features of this kind of honey is noteworthy. However, due to its rarity on the market, red raspberry honey is poorly characterized. The aim of this work was the phytochemical characterization of honey containing red raspberry from different geographical origins, through melissopalynological analyses concurrently with untargeted metabolomics achieved with different chromatographic techniques coupled to mass spectrometry: solid-phase micro-extraction/gas chromatography/mass spectrometry (SPME-GC-MS) and high-performance liquid chromatography/Orbitrap mass spectrometry (HPLC-Orbitrap). Results: Only 4 out of the 12 samples involved in the study contained raspberry pollen as dominant pollen, although these honeys did not group in the hierarchical cluster analysis nor in the classical multidimensional scaling analyses used for data evaluation. The first result was the detection of mislabelling in two samples, which contained raspberry pollen only as minor or important minor pollen. Of the 188 compounds identified by HPLC-Orbitrap and of the 260 identified by SPME-GC-MS, 87 and 31 compounds were present in all samples, respectively. The structurally related compounds nicotinaldehyde and nicotinamide, nicotinic acid and nicotinyl alcohol were present in 100% of the samples and correlated with R. idaeus pollen count (r > 0.60, Pearson's correlation analysis). Conclusion: This study reveals important aspects about the characterization of red raspberry honey and could give new insights on bee diet and preferences, since niacin compounds resulted interestingly to be related to the presence of red raspberry pollen. © 2024 Society of Chemical Industry. (© 2024 Society of Chemical Industry.) |
| References: | Codex Alimentarius Commission, Revised Codex Standard for Honey, CODEX STAN 12–1981, Rev. 1 (1987), Rev. 2 (2001). Bekić B, Jeločnik M and Subić J, Honey bee colony collapse disorder (Apis mellifera L.): possible causes. Scientific Papers Series Management, Economic Engineering in Agriculture and Rural Development 14:13–8. (2014). Kaškonienė V and Venskutonis PR, Floral markers in honey of various botanical and geographic origins: a review. Compr Rev Food Sci Food Saf 9:620–634 (2010). Machado AM, Miguel MG, Vilas‐Boas M and Figueiredo AC, Honey volatiles as a fingerprint for botanical origin: a review on their occurrence on monofloral honeys. Molecules 25:374 (2020). Visscher PK and Seeley TD, Foraging strategy of honeybee colonies in a temperate deciduous forest. Ecology 63:1790–1801 (1982). Leoni V, Giupponi L, Pavlovic R, Gianoncelli C, Cecati F, Ranzato E et al., Multidisciplinary analysis of Italian alpine wildflower honey reveals criticalities, diversity and value. Sci Rep 11:19316 (2021). Leoni V, Panseri S, Giupponi L, Pavlovic R et al., Formal analysis are fundamental for the definition of honey, a product representing specific territories and their changes: the case of North Tyrrhenian dunes (Italy). Sci Rep (2023). https://doi.org/10.21203/rs.3.rs-2937942/v1. Council Directive of the European Union, Council directive 2001/110/EC of 20 December 2001 relating to honey. Official J Eur Commun L10:47 (2002). Council Directive, 74/409/EEC of 22 July 1974 on the harmonization of the laws of the Member States relating to honey. Oddo LP, Piro R, Bruneau É, Guyot‐Declerck C et al., Main European unifloral honeys: descriptive sheets. Apidologie 35:S38–S81 (2004). Špánik I, Janáčová A, Šusterová Z, Jakubík T, Jánošková N, Novák P et al., Characterisation of VOC composition of Slovak monofloral honeys by GC× GC‐TOF‐MS. Chem Pap 67:127–134 (2013). Salonen A, Hiltunen J and Julkunen‐Tiitto R, Composition of unique unifloral honeys from the boreal coniferous forest zone: fireweed and raspberry honey. J ApiProd ApiMed Sci 3:128–136 (2011). Pauliuc D and Oroian M, Physico‐chemical parameters of Romanian raspberry honey. Food Environ Saf J 18:4 (2020). Kędzierska‐Matysek M, Florek M, Wolanciuk A, Barłowska J and Litwińczuk Z, Concentration of minerals in nectar honeys from direct sale and retail in Poland. Biol Trace Elem Res 186:579–588 (2018). Ramanauskiene K, Stelmakiene A, Briedis V, Ivanauskas L and Jakštas V, The quantitative analysis of biologically active compounds in Lithuanian honey. Food Chem 132:1544–1548 (2012). Lachman J, Orsák M, Hejtmánková A and Kovářová E, Evaluation of antioxidant activity and total phenolics of selected Czech honeys. LWT 43:52–58 (2010). Pauliuc D, Dranca F, Ropciuc S and Oroian M, Advanced characterization of monofloral honeys from Romania. Agriculture 12:526 (2022). Pauliuc D, Dranca F and Oroian M, Antioxidant activity, total phenolic content, individual phenolics and physicochemical parameters suitability for Romanian honey authentication. Foods 9:306 (2020). Pauliuc D, Dranca F and Oroian M, Raspberry, rape, thyme, sunflower and mint honeys authentication using voltammetric tongue. Sensors 20:2565 (2020). Scripcă LA and Amariei S, The influence of chemical contaminants on the physicochemical properties of unifloral and multifloral honey. Foods 10:1039 (2021). Ciursa P, Oroian M and Pauliuc D, Detection of raspberry honey adulterated with agave, maple, rice, corn and inverted sugar syrups using instrumental techniques. Ukr Food J 10:3–491 (2021). Salonen A, Virjamo V, Tammela P, Fauch L and Julkunen‐Tiitto R, Screening bioactivity and bioactive constituents of Nordic unifloral honeys. Food Chem 237:214–224 (2017). Seisonen S, Kivima E and Vene K, Characterisation of the aroma profiles of different honeys and corresponding flowers using solid‐phase microextraction and gas chromatography–mass spectrometry/olfactometry. Food Chem 169:34–40 (2015). Maurizio A and Louveaux J, Pollens de plantes mellifères d'Europe. Union des Groupements Apicoles Français, Lons‐le‐Saunier, impr. M. Declume, Paris (1965). Maurizio A and Schaper F, Das Trachtpflanzenbuch. Nektar und Pollen‐die wichtigsten Nahrungsquellen der Honigbiene, Ehrenwirth, München (1994). Whitney GG, The productivity and carbohydrate economy of a developing stand of Rubus idaeus. Can J Bot 60:2697–2703 (1982). Ricard JP and Messier C, Abundance, growth and allometry of red raspberry (Rubus idaeus L.) along a natural light gradient in a northern hardwood forest. For Ecol Manage 81:153–160 (1996). Giupponi L, Leoni V, Pedrali D and Giorgi A, Restoration of vegetation greenness and possible changes in mature forest communities in two forests damaged by the Vaia storm in northern Italy. Plants (Basel) 12:1369 (2023). Wight HM, Genome assembly and comparative RNA‐Seq visualization of red raspberry, Rubus Idaeus. Doctoral dissertation. University of Maryland, USA (2019). Louveaux J and Maurizio a Vorwohl G, Methods of melissopalynology. Bee World 59:139–157 (1978). Von Der Ohe W, Oddo LP, Piana ML, Morlot M et al., Harmonized methods of melissopalynology. Apidologie 35:S18–S25 (2004). Barth OM, Microscopical analysis of honey samples. An Acad Bras Cienc 42:351–366 (1970). Chen W, Wu S, Zhang J, Yu F, Hou J, Miao X et al., Matrix‐induced sugaring‐out: a simple and rapid sample preparation method for the determination of neonicotinoid pesticides in honey. Molecules 24:2761 (2019). Wang B, Ezejias T, Feng H and Blaschek H, Sugaring‐out: a novel phase separation and extraction system. Chem Eng Sci 63:2595–2600 (2008). Zhu Z, Zhang Y, Wang J, Li X, Wang W and Huang Z, Sugaring‐out assisted liquid‐liquid extraction coupled with high performance liquid chromatography‐electrochemical detection for the determination of 17 phenolic compounds in honey. J Chromatogr A 1601:104–114 (2019). Rusko J, Vainovska P, Vilne B and Bartkevics V, Phenolic profiles of raw mono‐ and polyfloral honeys from Latvia. J Food Compos Anal 98:103813 (2021). Pavlovic R, Borgonovo G, Leoni V, Giupponi L, Ceciliani G, Sala S et al., Effectiveness of different analytical methods for the characterization of propolis: a case of study in northern Italy. Molecules 25:504 (2020). Belardi RP and Pawliszyn JB, Application of chemically modified fused silica fibers in the extraction of organics from water matrix samples and their rapid transfer to capillary columns. Water Pollut Res J Can 24:179–191 (1989). Omanovic‐Miklicanin E, Valzacchi S, Simoneau C, Gilliland D and Rossi F, Solid‐phase microextraction/gas chromatography–mass spectrometry method optimization for characterization of surface adsorption forces of nanoparticles. Anal Bioanal Chem 406:6629–6636 (2014). Giupponi L, Leoni V, Pavlovic R and Giorgi A, Influence of altitude on phytochemical composition of hemp inflorescence: a metabolomic approach. Molecules 25:1381 (2020). Pavlovic R, Panseri S, Giupponi L, Leoni V, Citti C, Cattaneo C et al., Phytochemical and ecological analysis of two varieties of hemp (Cannabis sativa L.) grown in a mountain environment of Italian Alps. Front Plant Sci 10:1265 (2019). White JW, Beaty MR, Eaton WG, Hart B et al., Instrumental color classification of honey: collaborative study. J Assoc Off Anal Chem 67:1129–1131 (1984). Bertoncelj J, Doberšek UM and Golob T, Evaluation of the phenolic content, antioxidant activity and colour of Slovenian honey. Food Chem 105:822–828 (2007). Beretta G, Granata P, Ferrero M, Orioli M and Maffei Facino R, Standardization of antioxidant properties of honey by a combination of spectrophotometric/fluorimetric assays and chemometrics. Anal Chim Acta 533:185–191 (2005). R Core Team, R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing, Austria (2018). Demianowicz Z, Charakteristik der einartenhonige. Les Annales de l'Abeille 7:273–288 (1964). Oddo LP, Piazza MG, Sabatini AG and Accorti M, Characterization of unifloral honeys. Apidologie 26:453–465 (1995). Oddo LP, Sabatini AG, Accorti M, Colombo R et al. eds, I mieli unflorali italiani. Nuove schede di caratterizzazione. Ministero delle Politiche Agricole e Forestali, Roma (2000). Bogdanov S, Bieri K, Kilchenmann V and Gallmann P, Mieli uniflorali svizzeri. ALP forum 2005, n. 23 I. Stazione di ricerca Agroscope Liebefeld‐Posieux ALP, Centre for Research in Apiculture, Bern, Switzerland. Gismondi A, Di Marco G and Canini A, Detection of plant microRNAs in honey. PLoS One 12:e0172981 (2017). Bruni I, Galimberti A, Caridi L, Scaccabarozzi D, De Mattia F, Casiraghi M et al., A DNA barcoding approach to identify plant species in multiflower honey. Food Chem 170:308–315 (2015). Di Marco G, Gismondi A, D'Agostino A, Leonardi D and Canini A, Pilot study for environmental monitoring through beekeeping products of Pistoia territory. J Apic Res 1‐9:1–9 (2021). Di Marco G, Manfredini A, Leonardi D, Canuti L, Impei S, Gismondi A et al., Geographical, botanical and chemical profile of monofloral Italian honeys as food quality guarantee and territory brand. Plant Biosyst 151:450–463 (2017). Puścion‐Jakubik A, Borawska MH and Socha K, Modern methods for assessing the quality of bee honey and botanical origin identification. Foods 9:1028 (2020). Valverde S, Ares AM, Elmore JS and Bernal J, Recent trends in the analysis of honey constituents. Food Chem 387:132920 (2022). Borgonovo F, Marzorati S, Lucia P, Rizzi RM et al., Electronic nose for the classification of honeys of different floral origins. Chem Eng Trans 85:205–210 (2021). Isidorov VA, Czyżewska U, Jankowska E and Bakier S, Determination of royal jelly acids in honey. Food Chem 124:387–391 (2011). Gille A, Bodor ET and Ahmed K, Offermanns S nicotinic acid: pharmacological effects and mechanisms of action. Annu Rev Pharmacol Toxicol 48:79–106 (2008). Akimov MY, Koltsov VA, Zhbanova EV and Akimova OM, Nutritional value of promising raspberry varieties, IOP Conf. Ser. Earth Environ. Sci 640: 022078 (2021). Zhang X, Ahuja JK and Burton‐Freeman BM, Characterization of the nutrient profile of processed red raspberries for use in nutrition labeling and promoting healthy food choices. Nutr Healthy Aging 5:225–236 (2019). Lukas K, Harig T, Schulz S, Hadersdorfer J and Dötterl S, Flowers of European pear release common and uncommon volatiles that can be detected by honeybee pollinators. Chem 29:211–223 (2019). Dötterl S and Vereecken NJ, The chemical ecology and evolution of bee‐flower interactions: a review and perspectives. Can J Zool 88:668–697 (2010). El‐Sayed AM, Sporle A, Colhoun K, Furlong J et al., Scents in orchards: floral volatiles of four stone fruit crops and their attractiveness to pollinators. Chemoecology 28:39–49 (2018). Robertson GW, Griffiths DW, Woodford JAT, Birch ANE, Picket JA and Wadhams LJ, A comparison of the flower volatiles from hawthorn and four raspberry cultivars. Phytochemistry 33:1047–1053 (1993). Larcenaire C, Wang F, Holásková I, Turcotte R, Gutensohn M and Park YL, Characterization of the insect assemblage and associated floral volatiles of black cherry (Prunus serotina). Plants (Basel) 10:2195 (2021). Cordeiro GD and Dötterl S, Floral scents in bee‐pollinated buckwheat and oilseed rape under a global warming scenario. Insects 14:242 (2023). Panseri S, Manzo A, Chiesa LM and Giorgi A, Melissopalynological and volatile compounds analysis of buckwheat honey from different geographical origins and their role in botanical determination. J Chem 2013:11 (2013). Wu L, Liu W, Cao J, Li Q, Huang Y and Min S, Analysis of the aroma components in tobacco using combined GC‐MS and AMDIS. Anal Methods 5:1259–1263 (2013). Guyot C, Bouseta A, Scheirman V and Collin S, Floral origin markers of chestnut and lime tree honeys. J Agric Food Chem 46:625–633 (1998). Feulner M, Pointner S, Heuss L, Aas G, Paule J and Dötterl S, Floral scent and its correlation with AFLP data in Sorbus. Org Diversity Evol 14:339–348 (2014). Vivino AE and Palmer LS, The chemical composition and nutritional value of pollens collected by bees. Arch Biochem 4:129–136 (1944). AL‐Kahtani SN, Fatty acids and B vitamins contents in honey bee collected pollen in relation to botanical origin. Sci J King Faisal Univ 18:41–48 (2017). Barbieri D, Gabriele M, Summa M, Colosimo R, Leonardi D, Domenici V et al., Antioxidant, nutraceutical properties, and fluorescence spectral profiles of bee pollen samples from different botanical origins. Antioxidants 9:1001 (2020). Bisrat D and Jung C, Roles of flower scent in bee–flower mediations: a review. J Ecol Environ 46:3 (2022). Bascompte J, Mutualism and biodiversity. Curr Biol 29:R467–R470 (2019). Baker HG and Baker I, Studies of nectar‐constitution and pollinator‐plant coevolution, in Coevolution of Animals and Plants: Symposium V, First International Congress of Systematic and Evolutionary Biology. University of Texas Press, USA, pp. 100–140 (1973). Adler LS, The ecological significance of toxic nectar. Oikos 91:409–420 (2000). Singaravelan N, Nee'man G, Inbar M and Izhaki I, Feeding responses of free‐flying honeybees to secondary compounds mimicking floral nectars. J Chem Ecol 31:2791–2804 (2005). Stevenson PC, Nicolson SW and Wright GA, Plant secondary metabolites in nectar: impacts on pollinators and ecological functions. Funct Ecol 31:65–75 (2017). Hawkins J, De Vere N, Griffith A, Ford CR et al., Using DNA metabarcoding to identify the floral composition of honey: a new tool for investigating honey bee foraging preferences. PLoS One 10:e0134735 (2015). Thomson JD, Draguleasa MA and Tan MG, Flowers with caffeinated nectar receive more pollination. Arthropod‐Plant Interact 9:1–7 (2015). Hroncová Z, Havlík J, Stanková L, Hájková S, Titěra D and Rada V, Repellence and attraction of Apis mellifera foragers by nectar alkaloids. Sci Agric Bohem 47:14–17 (2016). Marchi IL, Palottini F and Farina WM, Combined secondary compounds naturally found in nectars enhance honeybee cognition and survival. J Exp Biol 224:jeb239616 (2021). Naef R, Jaquier A, Velluz A and Bachofen B, From the linden flower to linden honey: volatile constituents of linden nectar, the extract of bee‐stomach and ripe honey. Chem Biodivers 1:1870–1879 (2004). Beretta G, Artali R, Caneva E, Orlandini S, Centini M and Facino RM, Quinoline alkaloids in honey: further analytical (HPLC‐DAD‐ESI‐MS, multidimensional diffusion‐ordered NMR spectroscopy), theoretical and chemometric studies. J Pharm Biomed Anal 50:432–439 (2009). Beretta G, Caneva E and Facino RM, Kynurenic acid in honey from arboreal plants: MS and NMR evidence. Planta Med 73:1592–1595 (2007). Palmer‐Young EC, Tozkar CÖ, Schwarz RS, Chen Y, Irwin RE, Adler LS et al., Nectar and pollen phytochemicals stimulate honey bee (Hymenoptera: Apidae) immunity to viral infection. J Econ Entomol 110:1959–1972 (2017). Gherman BI, Denner A, Bobiş O, Dezmirean DS, Mărghitaş LA, Schlüns H et al., Pathogen‐associated self‐medication behavior in the honeybee Apis mellifera. Behav Ecol Sociobiol 68:1777–1784 (2014). Tissier ML, Kraus S, Gomez‐Moracho T and Lihoreau M, Supplementation in vitamin B3 counteracts the negative effects of tryptophan deficiencies in bumble bees. Conserv Physiol 11:coac084 (2023). Wright GA and Schiestl FP, The evolution of floral scent: the influence of olfactory learning by insect pollinators on the honest signalling of floral rewards. Funct Ecol 23:841–851 (2009). Svensson GP, Okamoto T, Kawakita A, Goto R and Kato M, Chemical ecology of an obligate pollination mutualism: testing the ‘private channel’ hypothesis in the Breynia‐Epicephala association. New Phytol 186:995–1004 (2010). Serra Bonvehí J and Ventura Coll F, Flavour index and aroma profiles of fresh and processed honeys. J Sci Food Agric 83:275–282 (2003). Soria AC, Martínez‐Castro I and Sanz J, Analysis of volatile composition of honey by solid phase microextraction and gas chromatography‐mass spectrometry. J Sep Sci 26:793–801 (2003). Bertelli D, Papotti G, Lolli M, Sabatini AG and Plessi M, Development of an HS‐SPME‐GC method to determine the methyl anthranilate in citrus honeys. Food Chem 108:297–303 (2008). de la Fuente E, Valencia‐Barrera RM, Martïnez‐Castro I and Sanz J, Occurrence of 2‐hydroxy‐5‐methyl‐3‐hexanone and 3‐hydroxy‐5‐methyl‐2‐hexanone as indicators of botanic origin in eucalyptus honeys. Food Chem 103:1176–1180 (2007). Cislaghi A, Giupponi L, Tamburini A, Giorgi A and Bischetti GB, The effects of mountain grazing abandonment on plant community, forage value and soil properties: observations and field measurements in an alpine area. Catena 181:104086 (2019). Giupponi L and Leoni V, VegeT: an easy tool to classify and facilitate the management of seminatural grasslands and dynamically connected vegetation of the Alps. Landarzt 9:473 (2020). Soria AC, González M, De Lorenzo C, Martınez‐Castro I et al., Characterization of artisanal honeys from Madrid (Central Spain) on the basis of their melissopalynological, physicochemical and volatile composition data. Food Chem 85:121–130 (2004). |
| معلومات مُعتمدة: | CN00000022 European Union Next-GenerationEU fund |
| فهرسة مساهمة: | Keywords: honey characterization; melissopalynology; nicotine compounds; red raspberry honey; untargeted metabolomics; volatile organic compounds |
| المشرفين على المادة: | 0 (Phytochemicals) |
| تواريخ الأحداث: | Date Created: 20240212 Date Completed: 20240614 Latest Revision: 20240614 |
| رمز التحديث: | 20240614 |
| DOI: | 10.1002/jsfa.13375 |
| PMID: | 38345434 |
| قاعدة البيانات: | MEDLINE |
Full Text Finder | تدمد: | 1097-0010 |
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| DOI: | 10.1002/jsfa.13375 |