Biochemical aspects of seeds from Cannabis sativa L. plants grown in a mountain environment

Photosynthetic pigments

The total content of carotenoids observed for both varieties was similar (4 mg/100 g) in certified and Viganella seeds; these values are in line with those reported in^8,15, whereas a higher amount was observed for Finola seeds of Crodo (Fig S3). The carotenoid/chlorophyll ratio of Finola seeds was lower compared with Futura 75, except for seeds from Viganella, which showed the highest ratio together with Futura 75 seeds from Crodo (0.66 and 0.68 respectively).

Currently there are few studies regarding carotenoids content of hempseeds, with the majority of them referring to the oil, however variations due to both genotype and year of cultivation were reported⁸. Carotenoids are part of the unsaponifiable fraction of hempseed oil, together with tocopherols and phytosterols, and their antioxidant activity contribute to preserve the oxidative stability of polyunsaturated fatty acids. Lutein was found to be the most abundant carotenoid in Finola, Futura and other five hemp varieties compared by⁸ and total carotenoid content can vary depending on both genotype and climatic conditions.

Considering that residual chlorophylls in seed reduce seed tolerance against stressful conditions, and the increase of the ratio of carotenoid to chlorophyll content is a measure of seed tolerance to stress¹⁶, we can suggest that Finola seeds from Crodo are less resistant than Finola seeds from Viganella.

Seed fatty acid profile

The results of fatty acid profiling of Finola and Futura 75 seeds and the total of saturated fatty acids (SFA), monounsaturated (MUFA), polyunsaturated (PUFA), omega-3 (ω3) and omega-6 (ω6) fatty acids are shown in Table ​Table22.

The principal SFA was palmitic acid (PA; 16:0) for Futura 75 (Viganella 7.21- Crodo 7.26%) and Finola (6.81–7.62%), followed by stearic acid (SA; 18:0) values of 3.20–2.78% in Futura 75, and 3.52- 2.71% in Finola seeds from the fields of Viganella and Crodo respectively. The total SFA content was similar in the two varieties (11.89–11.86% in Futura 75, and 11.41–11.29% in Finola grown in Viganella and Crodo). The most abundant unsaturated fatty acids in the seeds of the two varieties were linoleic acid (LA; C18:2 ω6c): 55.86–55.38% for Futura 75 and 56.18–57.34% in Finola grown in Viganella and Crodo, and oleic acid (OA; C18:1 ω9c): 13.53–11.38% for Futura 75 and 13.88–12.51% for Finola grown in Viganella and Crodo, respectively, with a lower value observed in certified seeds of Finola (8.82%). Similar amounts of ω3 linolenic acid (C18:3ω3) were found in certified seeds of both Futura 75 and Finola (16.4–15.88%) and Futura 75 seeds obtained from the two experimental fields (15.97–16.24%). Lower amounts were detected in Finola seeds from both Viganella and Crodo (8.76–8.57%). A significant amount of Cis-11-eicosenoic acid (C20:1) was found in Finola from the two experimental fields (7.64–7.65%), while low amounts (below 0.5%) were present in both certified and harvested seeds of Futura 75 and certified Finola seeds. According to this, the total MUFA percentage resulted higher in harvested seeds of Finola (21.65–20.35%) respect with harvested Futura 75 (14.06–11.98%) and certified seeds of both varieties (13–10.08%). PUFA represent the main source of fatty acids in the seeds of both varieties. A comparable amount was observed in certified (75.07%) and harvested seeds of Futura 75 (74.05–76.16%), while a slightly lower amount was detected in harvested (66.94–68.36%) compared with certified (77.58%) Finola seeds. Both the genotypes are rich in the two essential fatty acids (EFAs) LA (18:2 ω6) and α-linolenic acid (18:3 ω3). Futura 75 seeds from Crodo showed the highest content of γ-linolenic (GLA, 4.41%), which is comparable with the value observed in certified seeds of Finola (4.33%), while harvested Finola seeds presented a linolenic acid content two times lower than Futura 75, with consequently higher average values of ω6/ω3 ratio (6.59–6.96 Finola vs. 3.64–3.69 harvested Futura 75, and 3.58–3.80 certified seeds of Futura 75 and Finola). These observations are in accordance with⁹ where a decrease of ω3 linolenic acid and increase of Cis-11-eicosenoic acid were observed in seeds of Finola respect with Futura 75 plants grown in mountain environment of Italian Alps, with a similar ω6/ω3 ratio in Finola seeds (6.25).

Hempseeds represent a rich source of high quality fatty acids (representing the 25–35% of the seed) whose composition can vary among different cultivars, with possible adaptive significance. Both Futura 75 and Finola varieties grown in mountain fields have been shown as a good source of PUFA. According to the European Food and Safety Authority (EFSA) the ideal ω6/ω3 ratio is in the range 3:1–5:1 and the values obtained from hempseed oil of different cultivars fall within this range⁴. The ω6/ω3 ratios obtained for certified seeds of Finola and both certified and harvested seeds of Futura 75 are consistent with those reported in literature¹⁷, while harvested seeds of Finola contained lower amount of ω3 linolenic acid. The other significant variation observed in harvested Finola seeds regards the monounsaturated Cis-11-eicosenoic acid (C20:1, EA). EA presents interesting properties and is used as a raw material in the production of cosmetics, lubricant oils and pharmaceutical compounds. EA is a precursor of erucic acid in higher plants and the production of erucic acid is usually higher than EA. Its synthesis is supposed to be performed by D9-fatty acid elongase (D9EL) from oleic acid. Notably, a temperature dependent increase in the production of EA was observed in PUFA producer fungi belonging to Mortierella species, grown below 20°C¹⁸. Lysophosphatidylcholine acyltransferase 2 (LPCAT2) was found to be the principal determinant of variation in C20:1 content of A. thaliana seeds. Reduced expression of LPCAT2 is correlated with the enhanced production of EA at the expense of PUFA, shifting the fate of the acyl-CoA pool from the incorporation into phosphatidylcoline to the fatty acid elongation¹⁹.

The observed increase of MUFA in Finola seeds from the experimental fields suggests an adaptive plasticity to the environment of growth. It is widely demonstrated that fatty acid composition is related to temperature, which shows a positive correlation with saturated fatty acids content, while generally an increase of unsaturated acids is observed in plants growing at lower temperatures. In this study, high levels of linoleic acids were observed in all the analyzed seeds without statistical differences among the samples. A strong correlation between fatty acids composition and environmental factors such as elevation, maximum temperature and precipitation was observed in seeds of Sapindus spp., where EA specifically correlated with elevation²⁰. The lower linolenic acid and the higher EA content of harvested Finola respect with certified Finola and both harvested and certified Futura 75 seeds, confirm previous observations from another Italian Alpine environment⁹ possibly refecting an adaptation of Finola plants to this environment.

Protein analysis of sequential fractions

The sequential fractions and total protein extracts from seeds of Finola and Futura 75 cultivars grown in Crodo and Viganella experimental areas, together with certified seeds as a control, were analysed combining both SDS-PAGE and 2D-PAGE, in order to quickly visualize main differences in protein expression among cultivars and experimental fields, and to better characterize the distribution of hempseed proteins. The protein pattern of albumin and globulin fractions was similar in all the samples, except for those obtained from Finola seeds of Viganella, where a dramatic change due to the appearance of several spots at low molecular weight was observed (Figs. 1 and ​and22 and supplementary figures S4, S5). Concerning the glutelin-like fractions, no differences were observed among the samples (Fig. S6). The albumin fraction contains the highest heterogeneity of proteins and in attempt to identify their function, spots from this fraction were excised from the gels (Figs. 3 and ​and4)4) and analyzed by MS. The list of proteins that were identified from albumin fraction is indicated in Table ​Table33 and the peptide sequences are available in supplementary table S1.

The fractionation of albumins allowed the partial depletion of edestin, the most abundant storage protein of hempseeds, improving the detection of other proteins involved in metabolic functions of seeds. The presence of Luminal binding protein 5 (BiP) and HSP70-like was detected in spot 32, while a protein disulfide isomerase-like and chaperonine 60 (RuBisCO large subunit-binding protein subunit alpha) were identified in spot 33.

These two spots are observed in the upper left side of the gel, and their intensity is clearly lower in seeds of Finola grown in the field of Viganella, as observed for other high molecular weight proteins. During seed maturation, storage proteins are folded within the endoplasmic reticulum (ER). This process is assisted by chaperones of the HSP70/BiP (luminal binding protein) family and protein disulfide isomerase (PDI). HSP70/BiP chaperones bind transiently to the nascent polypeptides and prevent protein misfolding under normal and stress conditions^10,21, PDI catalyzes a thiol–disulfide exchange reaction leading to the formation of proper disulfide bonds that stabilize the structure of proteins²². Bips are implicated in the synthesis of storage proteins and stress response, however it was observed in transgenic rice that extreme BiP overexpression inhibited proper protein accumulation in protein bodies, resulting in floury and shrunken seeds, with low levels of seed storage proteins and starch contents compared with the wild type. On the contrary, PDI-overexpressing mutants present seeds with similar traits to the wild type²¹. PDI5 is necessary for seed development as it seems to be involved in the regulation of programmed cell death (PCD) by inhibition of Cys proteases during the trafficking to vacuoles. It was observed in Arabidopsis thaliana that the loss of PDI5 function led to premature PCD during embryogenesis and to the production of fewer, nonviable seeds²³. Interestingly, two spots sharing a similar position to 32 and 33 spots in the 2D-gel were identified as HSP70 and luminal-binding protein 5 from albumin/globulin fractions of quinoa seeds as well, and resulted to increase under salinity stress²⁴.

Besides the HSP70-like of spot 32, another form of HSP70 was identified in spot F, which was exclusive of Finola seeds grown in Viganella. This is probably a protein fragment because the observed molecular weight was lower than the theorethical one. Spots 13, 14, 15, 16 were identified as 18.5 kDa class I HSP protein like, and spot 47 was detected as 17.8 kDa class I HSP. These proteins are generally defined as “small Heat Shock Proteins” (sHSPs), characterized by a low molecular weight (12–40 kDa). Small HSPs present a short C-terminal sequence, a highly conserved α-cristallin domain (ACD), and a highly variable N-terminal region. These proteins act as chaperones which can form multimeric complexes and bind denatured proteins, preventing protein aggregation. Plant sHSPs belong to 6 classes, with class I including the cytoplasmic form^25,26.

The members of Heat Shock Proteins (HSP) 70 (DnaK in prokaryotes) are conserved proteins involved in folding processes including the folding of nascent proteins, protein transport across membranes, and refolding of misfolded and aggregated proteins²⁷. HSP70 and small heat shock proteins are implicated in heat sensitivity of plants and the overexpression of hsp70 often results in enhanced thermotolerance. Plastidial HSP70s are important for thermotolerance of germinating seeds, since plastids are involved in the assimilation of nitrogen and in the synthesis of lipids required during seed germination and growth^28,29. Besides their role against heat stress, HSPs are also involved in seed development. Abscisic acid (ABA) is a plant hormone that plays a role in seed dormancy and germination control. It was observed that ABA auxotroph plants present enhanced germination and produce viviparous seeds³⁰. A form of HSP70 was found to be necessary to establish the basal level of transcription of Abscisic acid (ABA)-responsive genes, suggesting a role in the long-term adaptation to drought and dehydration tolerance in vegetative tissues and/or seeds³¹. HSPs are highly expressed in mature and dry seeds, whereas they tend to disappear during germination³². 1-Cys peroxiredoxin (PER1) and glutathione S-transferase DHAR2-like were identified in spot 53, which is observable in all samples except for Finola seeds obtained from Viganella field. PER1 was also detected in spot 5, near to spot 53. The presence of spot 5 is more evident in seeds of Futura 75 obtained from the experimental fields of Crodo and Viganella. Spots 8 and 25 were identified as NADPH dependent aldehyde reductase 1. Spot 8 can be detected in the certified seeds of both varieties, while it decreases in Finola seeds from Viganella. On the contrary, seeds of Futura 75 grown in Viganella present both the spot 8 and a new spot (25), which was not observed in certified seeds. Reactive oxygen species (ROS) and reactive carbonyl species (RCS) are produced during seed storage, and might cause oxidative damage in seeds by oxidizing lipids to various aldehydes and ketones³³. An effective protection against such reactions is especially important in seeds rich of linoleic and linolenic acid, which are sources of short chain carbonyls after peroxidation. NADPH- aldehyde reductases act in the detoxification of reactive carbonyls in plants catalyzing their reduction on α,β-unsaturated aldehydes and saturated aldehydes such as methylglyoxal³⁴. Peroxiredoxins show antioxidant activity and can be divided into three classes: typical 2-Cys Prx, atypical 2-Cys Prx, and 1-Cys Prx (PER1), the latter being expressed in developing seeds. 1-Cys peroxiredoxin shows highest expression levels during the dehydration stages at the end of seed development and in the mature dry seed. It was suggested that PER1 is employed to sense and/or react to seed environmental conditions, preventing germination under unfavorable conditions³⁵. Glutathione-S-transferases (GSTs) are a diverse family of proteins that detoxify xenobiotic and endobiotic compounds by conjugating GSH and protect against ROS-induced oxidative damage. One group is represented by glutathione dependent dehydroascorbate reductases (DHARs) which catalyzes the GSH-dependent reduction of dehydroascorbate (DHA) to ascorbate, a reaction implicated in plant redox homeostasis³⁶. An increase of Glutathione-S-Tranferases (GST) and PER1 was observed in storage tolerant seeds respect with storage sensitive seeds, suggesting an enhanced seed tolerance to aging by an effective ROS detoxification using antioxidants such as GSTs and PER1³³. Two spots sharing the same MW/pI parameters of spots 5 and 53 on 2D gel were identified as PER1 in soybean seeds and seedlings³⁷, corresponding to a main protein form and a post-transationally modified form probably due to overoxidation, thus the two spots observed in hemp seeds could reflect a similar modification event.

The presence of PER1 in plants like soybean, rice and barley was reported to gradually decrease during germination. Observations on soybean demonstrated that the higher presence of PER1 in seedlings under flooding stress is not derived from newly synthesized protein, but is the result of delayed degradation³⁷.

Spots 54 and 55 are located in the basic end of the lower molecular weight zone of the gel and present higher dimensions respect with other spots. This is congruent with the identification of the basic subunits of the three edestin types. In addition to these, 11 kDa late embryogenesis abundant protein (LEA) and CYP19-4 a cyclophilin with peptidyl-prolyl cis–trans isomerase (PPI) activity were identified in spot 54, while 60S ribosomal protein L12-3-like was detected in spot 55. Another LEA group 3-like of C. sativa was identified in spot 59, which is highly visible in certified seeds of Futura 75. Late embryogenesis abundant (LEA) proteins accumulate in seeds during the late developmental stage and represent an important response to adverse conditions such as dessiccation and freezing by acting as hydration buffers and stabilizing cell structures. LEA proteins can be classified into seven groups, of which 3 LEA proteins seem to be important for the establishment of tolerance to low temperature stress in seeds by protecting antioxidant enzymes such as peroxidase and superoxide dismutase³⁸. The peptidyl-prolyl cis–trans isomerases (PPI) assist folding by catalyzing the cis–trans isomerization of Proline containing peptide bonds, a rate-limiting step in the folding of some proteins. It was observed in Arabidopsis plants that CYP19-4 is expressed during embriogenesis, assisting the folding and modulating the activity of EMB30/GNOM³⁹.

Finally, spot 3 was identified as phosphoglycerate kinase by detecting two peptides from a cytosolic form from Nicotiana tabacum and Arabidopsis thaliana in the Swiss Prot database, which currently (23rd December 2020) contains only 19 reviewed proteins of C. sativa. Two more peptides were homology identified after searching the NCBInr database (Viridiplantae), each peptide belonging to a different organism. After Blast analysis, the same peptides were found in three hypothetical proteins of C. sativa: F8388_017609, G4B88_025149, G4B88_011096 (KAF4350031.1, KAF4347106.1, KAF4347679.1) which share a very similar sequence. The only difference observed is peptide R.VDLNVPLDDSLKITDDTR.I, which shows the R.VDLNVPLDDNLTITDDTR.V sequence in C. sativa, with the different aminoacids in bold letters. The presence of T instead of K is consistent with the length of the observed peptide, otherwise it should be considered as a missed trypsin cleavage site. Phosphoglycerate kinase (PGK) is a monomeric enzyme of the glycolytic pathway which catalyzes the formation of ATP and 3-phosphoglycerate. On 2D maps, spot 3 is about 50 kDa and pI 5.5: phosphoglycerate kinase of N. tabacum and A. thaliana show similar parameters, whereas the three hypothetical proteins of C. sativa present longer sequences: according to ProtParam⁴⁰ their MW/pI are around 92 kDa and 6.0 respectively. Due to the high similarity of the sequences, KAF4347679.1 was chosen among the three hypothetical proteins of C. sativa and was compared with the sequence of two phosphoglycerate kinases (chloroplastic and cytosolic) of A. thaliana. Interestingly, all the detected peptides are located in the second part of the sequence, while the GVTTIIGGGDSVAAVEK peptide is repeated twice in the sequence. In order to predict the cellular location of KAF4350031.1, this sequence was analyzed with DeepLoc 1.0, a tool for the prediction of eukaryotic protein subcellular localization⁴¹. Analysis of the entire sequence led to chloroplast prediction, while the analysis starting from aa 477 (MATK) led to cytosolic prediction. Since the sequence of Hypothetical protein F8388_017609 (KAF4350031.1) of C. sativa is the result of a genome assembly experiment, it is possible that this sequence includes two isoforms (chloroplastic and cytosolic) of phosphoglycerate kinase.

The spots at low molecular weight that were mainly observed in Finola samples from Viganella were frequenty identified as fragments of edestin, the main globulin of hemp.

Total protein fraction

Globulins represent the primary storage proteins of legumes and oilseeds. With the aim to follow changes affecting the protein pattern of both globulins and metabolic proteins, a total protein extraction was performed and the proteins were separated by SDS-PAGE and 2D-PAGE. The profile of total proteins obtained after SDS-PAGE (Fig. 5) revealed the presence of different bands from 15 to > 75 kDa.

The three most intense bands are visible at 30, 20 and 18 kDa, corresponding to the molecular weight of the acidic and basic chains of edestin subunits, respectively. A less intense band is present around 45 kDa, with a marked decrease of intensity in seeds of Finola plants grown in the Viganella field. Other minor bands at a molecular weight higher than 75 kDa are more evident in certified seeds, while protein extracts from the experimental fields show more evident bands at low molecular weight (< 18 kDa) respect with certified seeds of both varieties.

The list of identified proteins from bands is reported in Table ​Table4,4, whereas the peptide sequences obtained after MS/MS analysis are reported in supplementary table S2. As expected, the most intense bands present isoforms belonging to the three different types of edestin, with a variable number of identified peptides among different seed samples. The identified peptides from the 30 kDa band belong to the acidic subunit (A8, A9, E1, E2, F1, F2, B8, B9). The band at about 20 kDa (L1) contain peptides belonging to the basic subunit of edestin type1, while the two bands around 18 kDa (from L2 to L5) contain a mixture of peptides mainly belonging to the basic subunit of edestin type2 and type3. Few peptides of edestin 1, Vicilin C72-like and a heat shock 70 kDa protein-like were identified from bands at high molecular weight (> 75 kDa, A1-A6, B1-B6).

Based on the sedimentation coefficients, globulins are classified as 7S (vicilin-like) and 10-12S (legumin-like) globulins. Legumin-like globulins are hexamers (300–370 kDa) composed of six subunits of about 50–60 kDa, where each subunit is post-translationally cleaved to obtain acidic (N-terminal, 30 kDa) and basic (C-terminal, 20–22 kDa) chains, linked by a disulfide bond formed in the precursor protein. Vicilin-like proteins, the second group of seed globulins, are trimers of 150–190 kDa composed of subunits of different molecular weight (50–70 kDa). Unlike the majority of 10-12S globulins, 7S globulins are generally glycosylated and can not form disulfide bonds¹⁰. Edestin is the 11S globulin contained in protein bodies of hempseeds, showing a structure similar to that of soy glycinin⁴². Previous works on hemp protein isolates analyzed by SDS-PAGE detected the acidic subunit (AS) of edestin as a homogeneous band of 34 kDa, while the basic subunit (BS) in two different bands of about 20 and 18 kDa. Therefore the molecular weight of edestin in its hexameric form is estimated to be 300 kDa^43–45. Recently, genes encoding for different isoforms of edestin were identified from Carmagnola and Futura hemp cultivars: CsEde1, CsEde2 and CsEde3, where CsEde1and CsEde3 genes are co-localized on the same DNA segment^46,47. As inferred from the deduced protein sequences, the two isoforms of edestin type3 are particularly rich of sulphurated aminoacids, showing higher Cys content respect with edestin type1 and type2, whereas Met content is similar to that of edestin type2⁴⁷. Other minor storage proteins of hemp seeds are represented by 7S vicilin and 2S albumin. Two genes encoding for 2S albumin clustered together in a tail-to-head array, and one gene encoding for a 7S vicilin-like were identified and characterized. The deduced 7S protein is a single polypeptide of 53.51 kDa containing two cupin_1 domains, four putative glycosylation sites within the cupin domains, and no inter-chain disulfide bonds⁴⁷. The presence of a 7S minor polypeptide of about 48.0 kDa was observed on polyacrylamide gels^43–45. We identified the following proteins belonging to the 7S family: vicilin C72-like, sucrose-binding protein-like and 7S vicilin-like.

Vicilin C72-like was detected mainly at 45 kDa from a defined band which was well defined in all samples except for Finola extracts obtained from the Viganella field, showing a marked decrease of intensity. Vicilin C72 was detected with the highest number of peptides in bands from certified seeds of both varieties (A7, B7) and with a progressively lower number of peptides in samples from Crodo (C1, D1) and the lowest number of peptides detected in Finola samples from Viganella (I2). The identified peptides belong to the protein sequence spanning from aa 467 to 824. Vicilin C72-like was also detected with a high number of peptides in 30 kDa bands, mainly F2 and I3, covering the protein sequence from aa 514–824. This protein contains two cupin_7S_vicilin-like domains spanning from aa 438 to 622 and from aa 643 to 812, and a Vicilin_N superfamily located at the N-terminal of cupin domain, from aa 308 to 383 (accession cd02244, cd02245 and cl23732 in the conserved domain database of NCBI (http://www.ncbi.nlm.nih.gov/Structure/cdd). Peptides from the Vicilin_N_superfamily domain were not detected from this band and the MW calculated with the ProtParam tool⁴⁰ is consistent with the apparent molecular weight observed on the gel, suggesting post/co-translational modification events. Sucrose-binding protein-like (SBP) contains two cupin_7S_vicilin-like domains spanning from aa 102 to 275 and from 305 to 467. SBP was detected at 45 kDa mainly in certified samples (A7, B7), while fewer matches were obtained from samples of the experimental fields (C1, D1, I2). The identified peptides cover the protein sequence from aa 170 to 474. SBP was also detected at 32–35 kDa (A8, A9, B8, F2) and, in samples of Finola Viganella, at lower molecular weight (25–30 kDa, I3, I5, I6). The peptides that were detected in these bands cover protein sequence from aa 204 to 474, with an estimated MW of 31 kDa.

Finally, the 7S vicilin-like protein was identified in bands around 25–30 kDa (E3, G1, H2, I4, I6) of samples from both experimental fields and certified seeds. The analysis of conserved domains revealed the presence of two cupin domains from aa 66 to 226 and from aa 321 to 470.

Vicilin C72-like, sucrose-binding protein-like and 7S vicilin-like all contain two cupin-like domains with a beta-barrel folding typical of 7S seed storage proteins such as beta-conglycinin, phaseolin, and a sucrose binding protein of soybean. Beside storage function, these proteins can act as antioxidants and seem to play defensive role in germinating seeds. These proteins are cleaved into fragments before and during the germination process, with some of them presenting antimicrobial activity, as observed in macadamia seeds⁴⁸.

Finally, despite the low reducing power of the SDS-PAGE technique, metabolic proteins less abundant than seed storage proteins, were identified. NADPH dependent aldehyde reductase 1, already detected in spot 8 and 25 of the albumin fraction, was found at 32–35 kDa (A9, B9, E2, F2) from certified and Crodo samples of both varieties, and at 25 kDa (I5) from Finola samples of Viganella. Lactoylglutathione lyase was detected at 30 kDa (A9, B9) and at 25 kDa (I5). This enzyme is involved in the first step of methylglyoxal detoxification forming S-lactoylglutathione. The ADP-rybosylation factor 1 (ARF1) was detected in the band C1 (total extracts), spot 3 and spot N (albumins) of Finola samples from Viganella field. ARF1 is a GTP-binding protein involved in the formation of vesicles, playing a role in coat protein complex I (COPI)-mediated retrograde trafficking. ARF1 is targeted to the Golgi and endosomes, with the active form associated to the membrane, whereas the inactive form of ARF1 is cytosolic⁴⁹.

Seed weight

The seed weight was assessed for each variety and source (certified or harvested seeds from the experimental fields) by weighing a sample of 50 seeds, randomly selected, using an analytical balance (Quintix, Sartorius) and repeated in triplicate.

Extraction and quantification of photosynthetic pigments

The photosynthetic pigments were extracted from 50 hempseeds and two biological replicates were considered. The seeds were ground in a mortar, then 0.1 g were taken and placed in a screw cap tube with 4 ml of 90% acetone. The tubes were wrapped with aluminum foil and stored at 4 °C for 16 h. After incubation, the tubes were vortexed at room temperature and the precipitate was left to settle, then 1 ml of the supernatant was transferred to a quartz cuvette (1 cm optical path) closed with a Teflon cap to prevent acetone evaporation. The samples were read at the spectrophotometer (SAFAS UV mc2 180–1050 nm), using the SAFAS SP2000 software (6.7 version) for data acquisition and processing. A wavelength scan from 350 to 700 nm was performed for each sample. Subsequently, the chlorophyll was transformed into pheophytin by acidifying the solution with 10 μl of HCl 0.1 N. Ten minutes after, a second spectrum was measured. The chlorophyll content was calculated using the equation described by Steinman et al.⁵⁴ while total carotenoids were estimated using the Züllig Equation⁵⁵.

Seed fatty acids composition

Seed samples of the investigated varieties were ground using superfine grinding extractor—intensive vibrational mill (Model MM400, Retsch GmbH, Haan, Germany). To obtain a representative seed powder, a 50 ml jar with 20 mm stainless steel balls at a frequency of 25 Hz for 1 min was used. Lipid extraction⁵⁶ was performed using 7.0 g of powdered seeds. The seed oil was extracted by a Soxhlet extractor and petroleum ether for 6 h at 60 °C. n-Hexane was used as the solvent and following the extraction method oil was separated from n-hexane using a rotator apparatus. The fatty acid composition of hemp seeds was determined using GC. In this method, the fatty acids were turned volatile using the method of methyl esterification⁵⁷. The prepared solution was injected into a GC Trace Ultra (ThermoFisher Scientific) equipped with a flame ionization detector (FID), with the following specifications. Capillary column RTX-2560 (100 m × 0.25 mm id, 0.20 μm); the carrier gas was nitrogen, with the purity of 99.9%. The injector and the detector temperature were 260 and 280 °C, respectively. The oven temperature was kept at 100 °C for 5 min and increased to 240 °C at the rate of 4 °C per minute and maintained at 240 °C for 30 min^58,59, The chromatographic profiles of analyte were elaborated with an Azur Software (Analytical Technology, Brugherio, Italia). Identification and quantitative evaluation of fatty acids was realized comparing retention times and areas with the ones of FAMEs (Fatty Acid Methyl Esters) standard mixes. All the analyses were done in three biological replicates.

Protein extraction

Protein fractions were obtained from seeds produced by Finola and Futura 75 cultivars grown in the two experimental fields (Crodo and Viganella) following the sequential and the total protein extraction methods^60,61. Protein extracts obtained from certified seeds were used as a reference control. The sequential method was applied to recover proteins showing different solvent solubility. The albumin fraction was obtained by grinding 1.0 g of hempseeds in a mortar at the temperature of 4 °C and mixed with a solution of 10 mL of ultrapure water containing 1% of protease inhibitor cocktail for plant cell and tissue extracts (P9599, Sigma Aldrich). The mixture obtained was transferred to Teflon tubes and left at a temperature of 4 °C for 2 h, vortexing occasionally (ZX3, Advanced Vortex Mixer, VELP Scientifica). The sample was centrifuged at 10,000 × g/4 °C for 15 min. Then the supernatant has been transferred into new tubes and stored at 4 °C. A second extraction of the pellet was done by adding 10 mL of ultrapure water with 1% of protease inhibitor cocktail and repeating the procedure described. The second supernatant was added to the previous one and stored at − 20 °C until use. The pellet obtained from the previous step was used to recover the globulin fraction, performing its solubilization in 10 mL of Tris–HCl 50 mM pH 8.0 and NaCl 0.3 M and incubating for two hours at 4 °C. Then the homogenate was centrifuged at 10,000 × g, 4 °C for 15 min. The supernatant was transferred to a new tube and stored at − 20 °C, while the pellet was used to recover the prolamin-like fraction. The pellet was solubilized with 10 mL of 70% ethanol and 0.2% 2-mercaptoethanol, left for 3 h at 4 °C and centrifuged at 10,000 × g, 4 °C for 30 min. The supernatant was transferred into a new tube and stored at − 20 °C. The pellet was dried (Concentrator plus, Eppendorf) and used to extract the final fraction of glutelin-like proteins. The pellet was mixed with 10 mL of NaOH 0.1 M, left at 4 °C for 2 h and then centrifuged at 10,000 × g for 30 min at 4 °C. The supernatant was stored at − 20 °C until use. Protein fractions obtained from the sequential extraction method were then precipitated in 10% Trichloroacetic acid (TCA)/Acetone and solubilized in 7 M urea, 2 M thiourea, 4% w/v CHAPS, 100 mM dithiothreitol (DTT), IPG-buffer (pH 3–10), in order to remove interfering salts for 2D-PAGE analyses.

Total proteins were extracted as indicated in⁶⁰. Hempseeds (1 g) were ground in a mortar at 4 °C and mixed with 20 ml of 10% TCA in cold acetone (− 20 °C), 20 mM DTT and 1% protease inhibitors cocktail (Sigma). The homogenate was filtered, transferred into tubes and incubated overnight at − 20 °C to allow complete protein precipitation. The samples were centrifuged (18,000 × g, 1 h, 4 °C), and the pellet was washed three times with cold acetone and finally dried. The protein pellet was solubilized 1 h at room temperature in 7 M urea, 2 M thiourea, 4% w/v CHAPS, 100 mM DTT, IPG-buffer (pH 3–10), occasionally vortexing.

The protein content of different extracts was estimated using the Bradford assay⁶² with bovine serum albumin (BSA) as the protein standard.

Protein analysis

Hempseed proteins resulting from sequential or total protein extractions were analyzed by sodium dodecyl sulphate–polyacrylamide gel electrophoresis (SDS-PAGE) and two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) followed by mass spectrometry (LC–MS/MS) protein identification.

For SDS-PAGE, 10 µg of protein extracts were mixed with Laemmli buffer (2% w/v SDS, 10% glycerol, 5% 2-mercaptoethanol, 62 mM Tris–HCl pH 6.8) and loaded onto 10 × 8 cm vertical 12% polyacrylamide gels.

For 2D-PAGE, 150 µg of albumin, globulin, glutelin-like and total protein extracts were mixed with rehydration buffer (9 M Urea, 4% CHAPS) and submitted to isoelectric focusing (IEF) using linear IPG-strips (pH 3–10, 7 cm, BioRad) using the following parameters: 7 h of passive rehydration followed by 7 h at 50 V, 15 min at 250 V with rapid voltage increase, 1 h with a gradual voltage increase up to 4000 V and focusing at 4000 V for a final amount of 20,000 V/hours. The strips were equilibrated in presence of SDS performing a reducing step with DTT (15 min) followed by an alkylation step with iodoacetamide (10 min) and finally loaded to a 12% polyacrylamide gel. A plug of protein standards (Precision Plus Protein Dual Color, Biorad) was loaded in order to estimate the apparent molecular weight of proteins, and the strips were sealed with 1% agarose solution. Both SDS-PAGE and 2D-PAGE second dimension were performed at 15 mA for 30 min and 30 mA with a Mini Protean System (BioRad). The running buffer was 25 mM Tris–HCl, 200 mM glycine, 0.1% w/v SDS. Gel staining was performed with Colloidal Coomassie brilliant blue G250 and the gel image was acquired by a GS-900 densitometer using the software ImageLab (BioRad).

Spot analysis of total protein extracts

The 2DE gels of total protein extracts obtained from certified and Viganella seeds of both varieties were analyzed using PDQuest software (BioRad) in order to detect spot differences among the tested samples. Four gels from three different biological replicates were compared for the analysis. Statistical analysis was performed using one-way ANOVA and differences were considered significant with p-value < 0.05.

This research was supported by the “FISR-MIUR Italian Mountain Lab” project. The authors also thank Dr Andrea Cottini—ArsUniVCO for the support with local farmers.