Next Article in Journal
Metabolite Differences of Polyphenols in Different Litchi Cultivars (Litchi chinensis Sonn.) Based on Extensive Targeted Metabonomics
Next Article in Special Issue
Extraction of Peppermint Essential Oils and Lipophilic Compounds: Assessment of Process Kinetics and Environmental Impacts with Multiple Techniques
Previous Article in Journal
Quantification and Metabolite Identification of Sulfasalazine in Mouse Brain and Plasma Using Quadrupole-Time-of-Flight Mass Spectrometry
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Molecules
Volume 26
Issue 4
10.3390/molecules26041180
molecules-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Chemical Fingerprinting of Cryptic Species and Genetic Lineages of Aneura pinguis (L.) Dumort. (Marchantiophyta, Metzgeriidae)

by
Rafał Wawrzyniak
1,*,
Wiesław Wasiak
1,
Beata Jasiewicz
1,
Alina Bączkiewicz
2 and
Katarzyna Buczkowska
2
1
Faculty of Chemistry, Adam Mickiewicz University in Poznań, Uniwersytetu Poznańskiego 8, 61-614 Poznań, Poland
2
Faculty of Biology, Adam Mickiewicz University in Poznań, Uniwersytetu Poznańskiego 6, 61-614 Poznań, Poland
*
Author to whom correspondence should be addressed.
Molecules 2021, 26(4), 1180; https://doi.org/10.3390/molecules26041180
Submission received: 17 January 2021 / Revised: 11 February 2021 / Accepted: 19 February 2021 / Published: 22 February 2021
(This article belongs to the Collection Essential Oils)
Browse Figures
Review Reports Versions Notes

Abstract

:
Aneura pinguis (L.) Dumort. is a representative of the simple thalloid liverworts, one of the three main types of liverwort gametophytes. According to classical taxonomy, A. pinguis represents one morphologically variable species; however, genetic data reveal that this species is a complex consisting of 10 cryptic species (named by letters from A to J), of which four are further subdivided into two or three evolutionary lineages. The objective of this work was to develop an efficient method for the characterisation of plant material using marker compounds. The volatile chemical constituents of cryptic species within the liverwort A. pinguis were analysed by GC-MS. The compounds were isolated from plant material using the HS-SPME technique. Of the 66 compounds examined, 40 were identified. Of these 40 compounds, nine were selected for use as marker compounds of individual cryptic species of A. pinguis. A guide was then developed that clarified how these markers could be used for the rapid identification of the genetic lineages of A. pinguis. Multivariate statistical analyses (principal component and cluster analysis) revealed that the chemical compounds in A. pinguis made it possible to distinguish individual cryptic species (including genetic lineages), with the exception of cryptic species G and H. The classification of samples based on the volatile compounds by cluster analysis reflected phylogenetic relationships between cryptic species and genetic lineages of A. pinguis revealed based on molecular data.

Graphical Abstract

1. Introduction

The genus Aneura Dumort. (Metzgeriidae) is a representative of the liverworts, a phylum of small terrestrial plants that has played an important role in the evolution of early land plants. Liverworts were among the first plants to colonize land [1,2], and they have been documented in the fossil record as early as 470 million years ago [3,4]. Today, liverworts are an important component of many terrestrial ecosystems [5]. Liverworts are also the source of a large number of biologically active compounds, such as terpenoids and aromatic compounds, synthesized and accumulated in oil bodies [6,7,8]. Many of these compounds occur only in liverworts and exhibit interesting biological activities [9,10,11,12,13,14]. These compounds are also a valuable source of markers for resolving taxonomic problems and identifying individual species [15,16,17,18,19,20]. Revealing differences in the composition of chemical compounds between closely related species is important not only for the identification of species but also for the clarification of evolutionary relationships between them [19,21,22,23].
Aneura pinguis (L.) Dumort., a common and widely distributed species, is an example of a simple thalloid liverwort, one of the three main types of liverwort gametophytes [24,25,26,27,28]. Aneura pinguis, although taxonomically treated as one species, from the biological point of view it is a complex of cryptic species, i.e., species which, in the absence of morphological differences, are reproductively isolated and have separate gene pools [29,30,31,32]. Recent molecular studies have revealed the existence of 10 cryptic species of A. pinguis that have been tentatively named with letters from A to J, genetic divergence between them in DNA sequences ranged from 1.45% to 7.41% [33]. Four of these species (A, B, C and E) are further subdivided into evolutionary lineages: species A and B into three lineages each (A1, A2, A3 and B1, B2, B3, respectively) and species C and E into two lineages each (C1, C2 and E1, E2, respectively)[33]. In total, 16 evolutionary lineages have been identified within A. pinguis at the molecular level. Eight cryptic species (14 evolutionary lineages) occur in Poland, and two species are not found in this region: species D discovered in Great Britain and species J limited exclusively to Japan [33]. Unfortunately, this high genetic diversity is not reflected in the presence of diagnostic features therefore individual cryptic species cannot be distinguished in the traditional way [31,32,33]. A helpful tool in identifying these species may be the analysis of the composition of chemical compounds.
Recently, chemotaxonomic studies of the genetically distinct cryptic species of A. pinguis revealed the presence of compounds specific to four cryptic species of A. pinguis (A, B, C and E) and A. maxima (Schiffn.) Steph. [34]. Differences in the composition and amount of volatile compounds were also found for evolutionary lineages distinguished based on molecular studies of species A (A1, A2, A3) and species B (B1, B2, B3). Thus, there is a close correlation between the chemical composition of the plant and its genotype [35].
The aim of this study was to determine the contents of volatile compounds in species C (lineages C1, C2), E (lineages E1, E2), G, H and I that have been recognized by molecular studies but whose chemical composition has not yet been analysed. In addition, we aimed to compare the chemical composition of genetically recognized cryptic species. Our ultimate goal was to evaluate the utility of the detected compounds as chemotaxonomic markers for identifying the cryptic species and evolutionary lineages of A. pinguis.

2. Results and Discussion

2.1. Chemical Profile

Thirty seven samples of A. pinguis belonging to seven different genetic lineages were subjected to chemical analyses. Volatile compounds were determined for the following species and genetic lineages (C1, C2, E1, E2, G, H and I) recognized based on molecular studies [33]. Details on locality and collection time of the samples are shown in Table 1. In the multivariate statistical analysis, results obtained in the present studies were compared with all remaining genetic lineages from previous research on A. pinguis [34,35]. As in previous studies, a small amount of biological material that could be collected for individual genetic lineages of A. pinguis from a given habitat in different vegetation seasons was determined using the HS-SPME technique.
Results of the chemical analyses are shown in Table 2, Table 3, Table 4 and Table 5. The tables also contain compounds of no. 9, 11, 57 and 58 provided in a previous study [35]. These data facilitate comparisons of the current results with those previously described.
To determine whether the chemical compounds can act as chemotaxonomic markers permitting the determination of all cryptic species of A. pinguis, the data obtained for samples in current studies (C1, C2, E1, E2, G, H, I) were compared in multivariate statistical analyses with data on the remaining genetic lineages of A. pinguis previously published [35]. Two classification methods were used: principal component analysis (PCA) and cluster analysis (CA). Both analyses were performed using all 66 volatile compounds detected in the examined A. pinguis samples.
In the cluster analysis, the classification of samples based on the volatile compounds largely reflected the phylogenetic relationships between cryptic species and genetic lineages of A. pinguis proposed by Bączkiewicz et al. [33] using molecular data. The chemical compounds found in A. pinguis make it possible to distinguish the vast majority of cryptic species and genetic lineages of the species (Figure 1). On the dendrogram constructed based on the Euclidean distance and Ward’s linkage method, 11 clusters can be recognized based on the Mojena index, which basically matched with the genetic lineages of A. pinguis, with the exception of two cryptic species: G and H, which form one cluster. The analysed samples of A. pinguis were grouped into two large clusters: the first cluster included species B, C, F, G, H, I and lineage E2, and the second cluster included A and lineage E1. All genetic units analysed in the present study (C1, C2, E1, E2, G, H and I) differed from the other species of A. pinguis (A, B and F) in the composition of chemical compounds, accounting for the fact that species A and B are divided into the genetic lineages A1, A2, A3 and B1, B2, B3, respectively. Samples of species C form two closely related clusters corresponding to the genetic lineages C1 and C2 based on molecular studies [33], however, these clusters differ to a lesser extent, like B2, B3, thus, on the basis of the Mojena’s index, they do not form separate clusters. In contrast, the two genetically closely related lines of species E (E1 and E2) show a high degree of distinctiveness in their chemical compounds [33]. Samples of lineage E1 formed a distinct group that was placed in one cluster with species A, which was similar to results of genetic studies; however, samples of E2 were in a second cluster that included species B, C, F, G, H, and I. The detected chemical compounds poorly differentiate between species G and H, whose distinction is supported by molecular studies [33].
To verify the patterns in diversity observed in the cluster analysis and express these data more simply, a PCA was conducted on the volatile compound data. PCA on the 66 compounds produced eight significant principal components (PCs) that explained 98.2% of the variation (R2X) and 75.4% the predicted variation (Q2). Figure 2 shows the three-dimensional scatter plot of the first three principal components, which explained 91.9% of the total variance included in the analysed volatile compounds. The PCA of the examined samples of A. pinguis revealed the existence of 13 groups of samples corresponding to the genetic lineages identified by DNA markers, because species G and H could not be distinguished. The PC1 axis primarily divided species B (genotypes B1, B2, B3) and F from G, H, I, A3 and E1 based on the relative content of compound 52, which made the largest contribution in PC1. The PC2 axis separated lineage A1 and A2 from A3 and lineage B3 from B1, B2 and F, while the PC3 axis differentiated lineage A1 from A2 and lineages B1, B3 and F from I and E1, which was the most distinct lineage in the PCA score plot. In contrast, the E2 genotype did not show strong differentiation from A1 and A2 (Figure 2). In the PC2 axis, compound 40 made the largest contribution, while in the PC3 axis, compounds 60 and 61 made the largest contributions; thus, these compounds played the most important role in separating genotypes across PC2 and PC3. From both statistical analyses (CA and PCA) is evident, that most species and genetic lineages of A. pinguis can be distinguished on the basis of their chemical composition. The differentiation and the degree of affinity between them revealed on the basis of chemical studies is almost completely consistent with the results of molecular analyzes [33]. An interesting exception is species E, lineages E1 and E2, which in terms of DNA sequences are closely related and belong to one clade (genetic divergence is equal to 0.38%), showing great diversity in the composition of chemical compounds and form strongly distinct sets. On the other hand, for the pair of species G and H, we observed small differences in the composition of chemical compounds, despite a significant molecular difference (2.47%) between them [33].
The 66 volatile compounds were determined based on chemical tests carried out on liverworts within A. pinguis, 40 of which were identified. The data collected in this paper and the work published by Wawrzyniak et al. [35] indicated that the composition of volatile compounds was primarily determined by genetics. Season and habitat appeared to have no effect on the chemical composition of compounds produced. The identified metabolites were compounds belonging to groups of oxygen derivatives of sesquiterpenes, sesquiterpenes, monoterpenes, aliphatic hydrocarbons and aromatic hydrocarbons. The observed differences in the composition of metabolites for individual A. pinguis genetic lineages were so salient that they could be used to identify biological material. Quite similar, Ludwiczuk et al. [21], demonstrated the use of volatile compounds as chemical markers for the identification of Conocephalum conicum cryptic species. The importance of the composition of volatile compounds as chemical markers is confirmed by the results of numerous studies of different liverwort species [8,18,19,20,21,22,23].
To simplify identification via metabolite composition, nine compounds from the group of 66 compounds examined that best differentiated the analysed material were selected that permit plant material to be assigned to specific species and even genetic lineages. Data on the content of these compounds for individual genetic lineages and species in the radar charts are shown in Figure 3.

2.2. Guide for the Identification of Cryptic Species and Genetic Lineages

These results also allowed us to prepare a guide describing a procedure through which different genetic lineages could be identified based on the content of marker compounds. The first step for identifying material is to characterize the content of pinguisone. The content of this compound can be used to classify the tested material into four groups (below 20%, 20–50%, 50–70% and above 70%). The next step is to determine the content of dihydrobryopterin A, which identifies lineages A3 and E1. Other groups can be identified based on the content of deoxopinguisone (species I) and costunolide (lineages C1, C2, B1, and species G, H). The absence of the compound characterized by IR = 1934 permits the identification of E2. The content of the compound characterized by IR = 1989 permits the differentiation of A1 and A2. The identification of lineages B2, B3, C2, and species F is based on the content of compounds characterized by IR = 1533 and IR = 1633. As seen in Figure 4, species G and H cannot be distinguished based on their chemical composition. The quantitative differences in the detected compounds are obviously not enough for identification of species G or H (e.g., compound IR = 1533 in Table 5).

3. Materials and Methods

3.1. Plant Material

Plant material included 37 samples of Aneura pinguis (L.) Dumort. (Aneuraceae) collected in different regions of Poland (Table 1). Some of the analysed genotypes of A. pinguis have small thallus sizes and often grow in small colonies composed of only a few thalli [32]. Several selected samples were collected repeatedly from the same place in consecutive years and at different times of the year (Table 1). From each sample, a portion was dried and deposited as a voucher in the POZW Herbarium. The remaining portion of the sample was cleaned and used for analyses. Samples for DNA and chemical analyses were stored at −30 °C. Chemical analyses were performed on samples of A. pinguis identified to species and genetic lineage based on six DNA barcodes; sequences were deposited in GenBank [33]. These sequences can be obtained from GenBank using the POZW numbers provided in Table 1.

3.2. GC Analysis of Volatile Compounds

The analysis of the volatile compounds was performed using a previously described GC-MS method [34,35]. Conditions of sorption and desorption were optimized through selection of the type of stationary phases, coated fibres, the amount of biological material, time, and temperature. Frozen 10 mg samples of A. pinguis were placed in a screw-capped vial with a 1.7 mL silicone/Teflon membrane. Next, the vial was heated at 50 °C, and headspace solid-phase micro-extraction was carried out for 60 min. SPME-fused silica fibres coated with divinylbenzene/carboxen/polydimethylsiloxane (DVB/CAR/PDMS) stationary phases were used (Sigma-Aldrich, St. Louis, MO, USA). Desorption was performed at 250 °C for 10 min. The above operations were carried out by the autosampler TriPlus RSH (Thermo Fisher Scientific, Waltham, MA, USA). Compounds isolated from the biological material were analysed by a gas chromatograph Trace 1310 coupled with a mass spectrometer ISQ QD (Thermo Fisher Scientific). The mass selective detector was operated at 70 eV in the EI mode over the m/z range 30–550 and temperature transfer line 250 °C. The GC instrument was equipped with a capillary column coating with the silphenylene phase (Quadex 007-5MS: 30 m × 0.32 mm i.d., film thickness 0.25 μm; Bethany, CT, USA). Helium was used as the carrier gas at a flow rate of 1.0 mL/min. The oven temperature was programmed to change from 60 to 230 °C at 4 °C/min and then remain stable at 230 °C for 40 min. Each sample was analysed three times.
After compound determination, the desorption procedure and GC analysis were repeated one more time. The lack of any peaks indicated that the selected conditions allowed the efficiency of the desorption process to reach 100%. The constituents were identified by comparing their MS spectra with those from the literature, reference compounds, computer matching against the NIST 11, data obtained from NIST Chemistry WebBook databases, Mass Finder 4 library, Adams library databases and Pherobase databases [36,37,38,39]. The identification of compounds was verified by Kovats retention indices. Kovats retention indices were determined relative to a homologous series of n-alkanes (C8–C26) under the same operating conditions. The relative concentrations of the components were obtained by peak area normalization without applying correction factors. The GC-MS analysis was performed in a scan mode; compounds were recorded via a TIC (total ion chromatogram). Table 2, Table 3, Table 4 and Table 5 show the data for compounds with concentrations greater than 0.01%. Recorded compounds below the 0.01% threshold were not included in the tables.

3.3. Statistical Analysis

Multivariate statistical data obtained in the current study for samples of lineages C1, C2, E1, E2, and species G, H, I were compared with data from the remaining genetic lineages of A. pinguis to determine whether the composition of volatile compounds differed within the group of cryptic species of A. pinguis that were studied [35]. Two classification methods were used: cluster analysis and principal component analysis. In cluster analysis, hierarchical clustering based on Euclidean distances according to Ward’s linkage method was used [40]. Principal component analysis was based on the covariance matrix of all 66 compounds using the nonlinear iterative partial least squares algorithm for constructing the PCA model. The v-fold method was used to find the optimal number of principal components that reached the maximum Q2. Statistical significance of the principal components was assessed based on the rule, Q2 > Limit. Statistical analyses were performed using STATISTICA 13.3 (StatSoft, Kraków, Poland).

4. Conclusions

GC-MS analysis of the volatiles revealed variability in the chemical composition of the various cryptic species of A. pinguis. The composition of volatile compounds in this species is largely genetically determined. The current and previous studies suggest that the selection of marker compounds might permit the rapid identification of almost all cryptic species of A. pinguis. These compounds include pinguisone (52) and its derivatives: deoxopinguisone (40), dihydrobryopterin A (55), and methyl norpinguisonate (56). Based on the content of these compounds, lineages E1 can be distinguished from A3 and I. The content of these compounds also permits the remaining lineages to be distinguished. The compounds IR = 1533 (37) and IR = 1633 (46) permit the differentiation of lineages B2, B3, C2 and species F. Costunolide (60) appears to be a robust chemical marker for lineage B1, C1, C2, and species G, H. The compound IR = 1934 (61) identifies lineage E2. Compound IR = 1989 (65) identifies lineage A1 and A2. The role of chemical compounds as chemotaxonomic markers for cryptic species of A. pinguis was supported by two multivariate statistical methods (CA and PCA), which grouped the studied samples based on the detected chemical compounds and was largely consistent with the genetic determination based on DNA barcoding sequences.

Author Contributions

Conceptualization, R.W. and K.B.; methodology, R.W. and K.B.; validation, R.W.; formal analysis, R.W. and K.B.; investigation, R.W., B.J., A.B., K.B.; resources, R.W., A.B. and K.B.; data curation, R.W., A.B. and K.B.; writing—original draft preparation, R.W. and K.B.; writing—review and editing, R.W. and K.B.; visualization, R.W. and K.B.; supervision, W.W.; project administration, R.W.; funding acquisition, R.W., W.W., A.B. and K.B. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by National Science Centre, grant number 2011/01/B/NZ8/00364 and 2013/09/B/NZ8/03274.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data presented in this study is available within the article.

Acknowledgments

We thank the Directors of the Bieszczady, Pieniny, Tatry and Wolin National Parks for their support provided during fieldwork and sampling of plant material. The authors thank A. Jarczewski for helpful discussion and suggestions.

Conflicts of Interest

The authors declare no conflict of interest.

Sample Availability

Not applicable.

References

  1. Cox, C.J.; Li, B.; Foster, P.G.; Embley, T.M.; Civáň, P. Conflicting phylogenies for early land plants are caused by composition biases among synonymous substitutions. Syst. Biol. 2014, 63, 272–279. [Google Scholar] [CrossRef]
  2. Edwards, D.; Morris, J.L.; Richardson, J.B.; Kenrick, P. Cryptospores and cryptophytes reveal hidden diversity in early land floras. New Phytologist. 2014, 202, 50–78. [Google Scholar] [CrossRef] [Green Version]
  3. Wellman, C.H.; Osterloff, P.L.; Mohiuddin, U. Fragments of the earliest land plants. Nature 2003, 425, 282–285. [Google Scholar] [CrossRef]
  4. Clarke, J.T.; Warnock, R.C.M.; Donoghue, P.C.J. Establishing a time-scale for plant evolution. New Phytol. 2011, 192, 266–301. [Google Scholar] [CrossRef]
  5. Konrat, M.; Hagborg, A.; Söderström, L.; Mutke, J.; Renner, M.; Gradstein, S.R.; Engel, J.; Zhu, R.L.; Pickering, J. Early Land Plants Today: Global Patterns of Liverwort Diversity, Distribution, and Floristic Knowledge. In Bryology in the New Millennium; Mohamed, H., Baki, B.B., Nasrulhaq-Boyce, A., Lee, P.K.Y., Eds.; University of Malaysia: Kuala Lumpur, Malaysia, 2008; pp. 425–438. [Google Scholar]
  6. Asakawa, Y. Progress in the Chemistry of Organic Natural Products, Volume 65. In Chemical Constituents of the Bryophytes; Herz, W., Kirby, W.B., Moore, R.E., Steglich, W., Tamm, C., Eds.; Springer: Vienna, Austria, 1995; pp. 1–618. [Google Scholar]
  7. Mues, R. Bryophyte Biology. In Chemistry Constituents and Biochemistry; Shaw, J.A., Goffinet, B., Eds.; Cambridge University Press: Cambridge, UK, 2000; pp. 150–181. [Google Scholar]
  8. Asakawa, Y.; Ludwiczuk, A.; Nagashima, F. Chemical Constituences of Bryophytes. Bio- and Chemical Diversity, Biological Activity, and Chemosystematics; Springer: Wien, Austria, 2013; pp. 1–665. [Google Scholar]
  9. Huang, W.J.; Wu, C.L.; Lin, C.W.; Chi, L.L.; Chen, P.Y.; Chiu, C.J.; Huang, C.Y.; Chen, C.N.; Marchantin, A. A cyclic bis(bibenzyl ether), isolated from the liverwort Marchantia emarginata subsp. tosana induces apoptosis in human MCF-7 breast cancer cells. Cancer Lett. 2010, 291, 108–119. [Google Scholar] [CrossRef]
  10. Xue, X.; Sun, D.F.; Sun, C.C.; Liu, H.P.; Yue, B.; Zhao, C.R.; Lou, H.X.; Qu, X.J. Inhibitory effect of riccardin D on growth of human non-small cell lung cancer: In vitro and in vivo studies. Lung Cancer 2012, 76, 300–308. [Google Scholar] [CrossRef]
  11. Yue, B.; Zhang, Y.S.; Xu, H.M.; Zhao, C.R.; Li, Y.Y.; Qin, Y.Z.; Wang, R.Q.; Sun, D.; Yuan, Y.; Lou, H.X.; et al. Riccardin D-26, a synthesized macrocyclic bisbibenzyl compound, inhibits human hepatocellular carcinoma growth through induction of apoptosis in p53-dependent way. Cancer Lett. 2013, 328, 104–113. [Google Scholar] [CrossRef]
  12. Iwai, Y.; Murakami, K.; Gomi, Y.; Hashimoto, T.; Asakawa, Y.; Okuno, Y.; Ishikawa, T.; Hatakeyama, D.; Echigo, N.; Kuzuhara, T. Anti-influenza activity of marchantins, macrocyclic bisbibenzyls contained in liverworts. PLoS ONE 2011, 6, e19825. [Google Scholar] [CrossRef]
  13. Sabovljevic, A.; Sokovic, M.; Sabovljevic, M.; Grubisic, D. Antimicrobial activity of Bryum argenteum. Fitoterapia 2006, 77, 144–145. [Google Scholar] [CrossRef]
  14. Zhang, L.; Chang, W.; Sun, B.; Groh, M.; Speicher, A.; Lou, H. Bisbibenzyls, a new type of antifungal agent, inhibit morphogenesis switch and biofilm formation through upregulation of DPP3 in Candida albicans. PLoS ONE 2011, 6, e28953. [Google Scholar] [CrossRef] [PubMed]
  15. Salimpour, F.; Mazooji, A.; Akhoondi, S. Chemotaxonomy of six Salvia species using essential oil composition markers. J. Med. Plants Res. 2011, 5, 1795–1805. [Google Scholar]
  16. Ethordević, B.S.; Pljevljakuśić, D.S.; Šavikin, K.P.; Stević, T.R.; Bigović, D.J. Essential oil from black currant buds as chemotaxonomy marker and antimicrobial agent. Chem. Biodiv. 2014, 11, 1228–1240. [Google Scholar] [CrossRef]
  17. Celiński, K.; Bonikowski, R.; Wojnicka-Półtorak, A.; Chudzińska, E.; Maliński, T. Volatiles as chemosystematic markers for distinguishing closely related species within the Pinus mugo complex. Chem. Biodiv. 2015, 12, 1208–1213. [Google Scholar] [CrossRef]
  18. Ludwiczuk, A.; Asakawa, Y. Chemosystematics of selected liverworts collected in Borneo. Trop. Bryol. 2010, 31, 33–42. [Google Scholar]
  19. Ludwiczuk, A.; Asakawa, Y. Fingerprinting of secondary metabolites of liverworts: Chemosystematic approach. J. AOAC Int. 2014, 97, 1234–1243. [Google Scholar] [CrossRef] [Green Version]
  20. Ludwiczuk, A.; Asakawa, Y. GC/MS fingerprinting of solvent extracts and essential oils obtained from liverwort species. Nat. Prod. Commun. 2017, 12, 1301–1305. [Google Scholar] [CrossRef] [Green Version]
  21. Ludwiczuk, A.; Odrzykoski, I.J.; Asakawa, Y. Identification of cryptic species within liverwort Conocephalum conicum based on the volatile components. Phytochemistry 2013, 95, 234–241. [Google Scholar] [CrossRef]
  22. Asakawa, Y. Chemosystematics of the Hepaticae. Phytochemistry 2004, 65, 623–669. [Google Scholar] [CrossRef]
  23. Ludwiczuk, A.; Gradstein, S.R.; Nagashima, F.; Asakawa, Y. Chemosystematics of Porella (Marchantiophyta, Porellaceae). Nat. Prod. Commun. 2011, 6, 315–321. [Google Scholar] [CrossRef]
  24. Szweykowski, J. Biodiversity of Poland, Volume 4. In An Annotated Checklist of Polish Liverworts and Hornworts; Mirek, Z.W., Ed.; Szafer Institute of Botany, Polish Academy of Sciences: Kraków, Poland, 2006; pp. 18–20. [Google Scholar]
  25. Crandall-Stotler, B.; Stotler, R.E.; Long, D.G. Bryophyte Biology, Morphology and Classification of the Marchantiophyta, 2nd ed.; Goffinet, B., Shaw, A.J., Eds.; Cambridge University Press: Cambridge, UK, 2009; pp. 1–54. [Google Scholar]
  26. Schuster, R.M. The Hepaticae and Anthocerotae of North America, Volume 5; Field Museum of Natural History: Chicago, IL, USA, 1992; pp. 551–574. [Google Scholar]
  27. Paton, J.A. The Liverwort Flora of the British Isles; Harley Books: Colchester, UK, 1999; pp. 537–540. [Google Scholar]
  28. Damsholt, K. Illustrated Flora of Nordic Liverworts and Hornworts; Nordic Bryological Society: Lund, Sweden, 2002; pp. 653–657. [Google Scholar]
  29. Bączkiewicz, A.; Sawicki, J.; Buczkowska, K.; Polok, K.; Zieliński, R. Application of different DNA markers in studies on cryptic species of Aneura pinguis (Jungermanniopsida, Metzgeriales). Cryptogam Bryol. 2008, 29, 3–21. [Google Scholar]
  30. Wachowiak, W.; Bączkiewicz, A.; Chudzińska, E.; Buczkowska, K. Cryptic speciation in liverworts – a case study in the Aneura pinguis complex. Bot. J. Linn. Soc. 2007, 155, 273–282. [Google Scholar] [CrossRef] [Green Version]
  31. Bączkiewicz, A.; Buczkowska, K. Differentiation and genetic variability of three cryptic species within the Aneura pinguis complex (Jungermanniidae, Marchantiophyta). Cryptogam Bryol. 2016, 37, 3–18. [Google Scholar] [CrossRef]
  32. Buczkowska, K.; Rabska, M.; Gonera, P.; Pawlaczyk, E.M.; Wawrzyniak, P.; Czołpińska, M.; Bączkiewicz, A. Effectiveness of ISSR markers for determination of the Aneura pinguis cryptic species and Aneura maxima. Biochem. Syst. Ecol. 2016, 68, 27–35. [Google Scholar] [CrossRef]
  33. Bączkiewicz, A.; Szczecińska, M.; Sawicki, J.; Stebel, A.; Buczkowska, K. DNA barcoding, ecology and geography of the cryptic species of Aneura pinguis and their relationships with Aneura maxima and Aneura mirabilis (Metzgeriales, Marchantiophyta). PLoS ONE 2017, 12, e0188837. [Google Scholar] [CrossRef] [Green Version]
  34. Wawrzyniak, R.; Wasiak, W.; Bączkiewicz, A.; Buczkowska, K. Volatile compounds in cryptic species of the Aneura pinguis complex and Aneura maxima (Marchantiophyta, Metzgeriidae). Phytochemistry 2014, 105, 115–122. [Google Scholar] [CrossRef]
  35. Wawrzyniak, R.; Wasiak, W.; Jasiewicz, B.; Ludwiczuk, A.; Bączkiewicz, A.; Buczkowska, K. High correlation of chemical composition with genotype in cryptic species of the liverwort Aneura pinguis. Phytochemistry 2018, 152, 134–147. [Google Scholar] [CrossRef]
  36. Stein, S.E. NIST Chemistry WebBook. NIST Standard Reference Database 69. Gaithersburg: National Institute of Standards and Technology. Available online: http://webbook.nist.gov/ (accessed on 14 January 2021).
  37. El-Sayed, A.M. The Pherobase: Database of Pheromones and Semiochemicals. Available online: http://www.pherobase.com/ (accessed on 14 January 2021).
  38. Joulain, D.; Knig, W.A.; Hochmuth, D.H. Terpenoids and Related Constituents of Essential Oils. Available online: https://massfinder.com/ (accessed on 14 January 2021).
  39. Adams, R.P. Identification of Essential Oil Components by Gas Chromatography/Mass Spectrometry, 4.1 ed. 2017. Available online: https://diabloanalytical.com/ms-software/essentialoilcomponentsbygcms/ (accessed on 14 January 2021).
  40. Ward, J.H., Jr. Hierarchical grouping to optimize an objective function. J. Am. Stat. Assoc. 1963, 58, 236–244. [Google Scholar] [CrossRef]
Molecules 26 01180 g001 550
Figure 1. Dendrogram of samples of cryptic species of A. pinguis (C, E, G, H, and I) compared with the remaining species of A. pinguis examined in a previous study [35]. The dendrogram was constructed based on the Euclidean distance according to Ward’s linkage method. The dendrogram was based on all of the detected compounds in the samples. The transverse line indicates the intersection of the dendrogram according to the Mojena index.
Figure 1. Dendrogram of samples of cryptic species of A. pinguis (C, E, G, H, and I) compared with the remaining species of A. pinguis examined in a previous study [35]. The dendrogram was constructed based on the Euclidean distance according to Ward’s linkage method. The dendrogram was based on all of the detected compounds in the samples. The transverse line indicates the intersection of the dendrogram according to the Mojena index.
Molecules 26 01180 g001
Molecules 26 01180 g002 550
Figure 2. Three-dimensional PCA score scatter plot based on all of the detected compounds in samples of cryptic species of A. pinguis (C, E, G, H, and I). The percentage of explained variance (R2X) was 81.4% for PC1, 6.2% for PC2, and 4.3% for PC3, and the predictive ability (Q2) was 36.7%, 16.7%, and 19.9%, respectively. Species in this study were compared with the remaining species of A. pinguis examined in a previous study [35].
Figure 2. Three-dimensional PCA score scatter plot based on all of the detected compounds in samples of cryptic species of A. pinguis (C, E, G, H, and I). The percentage of explained variance (R2X) was 81.4% for PC1, 6.2% for PC2, and 4.3% for PC3, and the predictive ability (Q2) was 36.7%, 16.7%, and 19.9%, respectively. Species in this study were compared with the remaining species of A. pinguis examined in a previous study [35].
Molecules 26 01180 g002
Molecules 26 01180 g003 550
Figure 3. Radar chart for marker compounds used to identify genetic lineages. The contents of compounds for individual genetic lineages are given in %.
Figure 3. Radar chart for marker compounds used to identify genetic lineages. The contents of compounds for individual genetic lineages are given in %.
Molecules 26 01180 g003
Molecules 26 01180 g004 550
Figure 4. Guide for the identification of cryptic species and genetic lineages of A. pinguis based on the content of marker compounds.
Figure 4. Guide for the identification of cryptic species and genetic lineages of A. pinguis based on the content of marker compounds.
Molecules 26 01180 g004
Table
Table 1. Sampling data of Aneura species used for studies and numbers of POZW herbarium vouchers.
Table 1. Sampling data of Aneura species used for studies and numbers of POZW herbarium vouchers.
Genotype GroupsSample CodeCollection PlaceGeographic
Coordinates		Date
mm.yyyy		POZW
Aneura pinguiscryptic species C
C1C1-1S Poland, Tatry Mts, NE slope of Skupniów Upłaz Mt.49°15′ N, 20°00′ E09.201442878
C1C1-2S Poland, Tatry Mts, valley of Biały Potok stream49°16′ N, 19°57′ E09.201442877
C1C1-3S Poland, Tatry Mts, Sucha Woda Valley49°16′ N, 20°01′ E09.201442819a
C1C1-4S Poland, Tatry Mts, Sucha Woda Valley49°16′ N, 20°01′ E06.201542819b
C1C1-5SE Poland, Bieszczady Mts, banks of Górna Solinka stream49°07′ N, 22°29′ E08.201442875
C1C1-6NW Poland, Western Pomerania, Słupia river54°15′ N, 17°29′ E06.201442874
C1C1-7NW Poland, Western Pomerania, Lake Garczyn54°07′ N, 17°54′ E06.201442873
C1C1-8NW Poland, Western Pomerania, Lake Kulkówko54°04′ N, 17°51′ E06.201442912a
C1C1-9NW Poland, Western Pomerania, Lake Kulkówko54°04′ N, 17°51′ E11.201442912b
C1C1-10NW Poland, Western Pomerania, Lake Kulkówko54°04′ N, 17°51′ E06.201542912c
C2C2-1SE Poland, Bieszczady Mts, valley of Beskidnik stream49°06′ N, 22°29′ E07.201942940
C2C2-2SE Poland, BieszczadyMts, valley of Górna Solinka stream49°06′ N, 22°31′ E07.201442792
C2C2-3SE Poland, Bieszczady Mts, Ustrzyki Górne, small stream49°05′ N, 22°38′ E07.201442880
C2C2-4SE Poland, Bieszczady Mts, valley of Terebowiec stream49°06′ N, 22°42′ E07.201942939
Aneura pinguiscryptic species E
E1E1-1S Poland, Tatry Mts, valley of Biały Potok stream49°16′ N, 19°57′ E09.201442824a
E1E1-2S Poland, Tatry Mts, valley of Biały Potok stream49°16′ N, 19°57′ E06.201542824b
E1E1-3S Poland, Tatry Mts, valley of Biały Potok stream49°16′ N, 19°57′ E09.201542824c
E1E1-4S Poland, Tatry Mts, Wielka Sucha Dolina valley49°16′ N, 19°49′ E09.201540521
E1E1-5S Poland, Tatry Mts, Pańszczyca Valley49°15′ N, 20°02′ E09.201540520
E2E2-1S Poland, Pieniny Mts, Limbargowy Potok stream49°25′ N, 20°21′ E08.201442888a
E2E2-2S Poland, Pieniny Mts, Limbargowy Potok stream49°25′ N, 20°21′ E08.201542888b
E2E2-3S Poland, Pieniny Mts, valley Biały Potok stream49°25′ N, 20°23′ E09.201942938
E2E2-4S Poland, Pieniny Mts, Kotłowy Potok stream49°24′ N, 20°24′ E08.201842937
Aneura pinguiscryptic species G
GG-1SE Poland, Bieszczady Mts, Beskid Pass49°03′ N, 22°46′ E07.201442896
GG-2S Poland, Beskidy Mts, Dejakowy Potok stream49°36′ N, 19°31′ E09.201242897
GG-3NE Poland, Suwałki Lake District, lake Druce54°06′ N, 23°21′ E05.201742934
GG-4NW Poland, Western Pomerania, Lake Małe Płocice54°05′ N, 17°51′ E06.201442767
Aneura pinguiscryptic species H
HH-1NW Poland, Western Pomerania, Lake Małe Sitno54°16′ N, 17°30′ E06. 201842936
HH-2Central Poland, Wielkopolska, valley of Rurzyca river53°17′ N, 16°44′ E10.201442898
HH-3S Poland, Śląsk, near Katowice50°14′ N, 19°00′ E06.201442755
HH-4NE Poland, Suwałki Lake District, Lake Sejny54°07′ N, 23°19′ E05.201942935
Aneura pinguiscryptic species I
II-1NW Poland, Western Pomerania, Lake Małe Oczko54°03′ N, 18°00′ E06.201442760a
II-2NW Poland, Western Pomerania, Lake Małe Oczko54°03′ N, 18°00′ E11.201442760b
II-3NW Poland, Western Pomerania, Lake Małe Oczko54°03′ N, 18°00′ E06.201542760c
II-4NW Poland, Western Pomerania, Lake Duże Sitno54°16′ N, 17°29′ E06.201442899a
II-5NW Poland, Western Pomerania, Lake Duże Sitno54°16′ N, 17°29′ E11.201442899b
II-6NW Poland, Western Pomerania, Lake Duże Sitno54°16′ N, 17°29′ E06.201542899c
Table
Table 2. Volatile compounds detected in the analyzed samples of genetic lineage C1 of the A. pinguis.
Table 2. Volatile compounds detected in the analyzed samples of genetic lineage C1 of the A. pinguis.
No.CompoundsRI aCode b
C1-1C1-2C1-3C1-4C1-5C1-6C1-7C1-8C1-9C1-10
11-Penten-3-ol6730.270.320.490.390.110.090.130.110.190.21
2Pentanal677----------
3(Z)-2-Penten-1-ol7660.090.110.210.220.090.110.100.060.080.12
4Hexanal7732.210.690.811.091.972.491.320.840.910.89
5(Z)-3-Hexen-1-ol8581.822.411.621.820.892.711.731.431.070.98
61-Hexanol8673.395.432.221.731.521.901.482.292.071.87
7α-Pinene936----------
8Camphene953----------
9Benzaldehyde970----------
10β-Pinene9780.390.100.190.210.510.110.390.120.440.23
11δ-Elemene1324----------
12α-Longipinene13500.220.020.030.060.120.030.020.080.060.05
13α-Ylangene13730.290.120.220.230.110.120.060.290.130.23
14α-Copaene1376----------
15Sativene13960.130.200.410.320.290.230.030.070.110.06
16β-Caryophyllene14150.690.280.630.430.120.320.180.650.430.52
17Longifolene14170.890.411.081.060.980.570.490.830.711.20
18β-Ylangene14230.810.730.510.700.540.590.380.620.610.30
19Cedrene14272.722.222.713.911.200.890.802.392.332.41
20204[M]+, 161 (100), 105(85)1431----------
21Thujopsene14350.380.701.312.182.390.060.100.180.100.09
22α-Guaiene1439----------
23204[M]+, 93(100), 81(82)1441----------
24204[M]+, 93(100), 79(85)1443----------
25204[M]+, 119(100), 93(75)14450.380.130.290.520.210.050.060.110.080.72
26α-Himachalene14470.100.050.080.110.040.210.120.220.090.10
27204[M]+, 91(100), 105(93)14530.220.100.080.230.070.210.100.180.080.22
28Alloaromadendrene14570.400.040.170.090.320.130.230.070.050.48
29γ-Gurjunene14700.120.060.040.390.050.210.090.070.080.41
30β-Himachalene15000.200.040.060.11------
31204[M]+, 119(100), 91(70)15030.190.060.070.090.210.090.060.210.060.11
32Cuparene1505----------
33δ-Cadinene1517----------
34β-Sesquiphellandrene15200.030.060.070.320.060.070.110.120.060.12
35204[M]+, 119(100), 91(66)1524----------
36204[M]+, 69(100), 91(38)1530----------
37216[M]+, 109(100), 145(75)15330.990.691.191.091.084.594.782.892.673.11
38α-Copaene-11-ol1540----------
39Longicamphenylone1559----------
40Deoxopinguisone156315.6911.8214.3913.4920.2111.6912.4220.4117.2216.70
41220[M]+, 91(100), 110(90)1585----------
42204[M]+, 137(100), 81(60)1593----------
43218[M]+, 91(100), 119(57)16030.810.620.110.400.130.220.080.590.570.87
44220[M]+, 135(100), 91(60)1620----------
45220[M]+, 110(100), 91(97)1626----------
46220[M]+, 91(100), 79(82)16330.292.370.691.180.511.381.590.610.821.33
47Longiverbenone1641----------
48δ-Cadinol1646----------
49Aromadendreneoxide-(2)1678----------
50222[M]+, 95(100), 81(75)16850.090.220.190.510.630.210.110.410.090.63
51220[M]+, 81(100), 67(90)16870.610.700.780.630.130.320.690.611.020.23
52Pinguisone170556.3958.1255.9155.3350.2850.6751.7047.0847.4251.08
53Isopinguisone1712----------
54Bryopterin A1735----------
55Dihydrobryopterin A17550.122.993.181.520.120.210.320.420.510.05
56Methyl norpinguisonate1791----------
57236[M]+, 95(100), 109(85)1846----------
58244[M]+, 189(100), 105(15)1851----------
59246[M]+, 192(100), 91(43)1882-----0.080.090.110.120.13
60Costunolide19146.816.298.728.3812.6117.9918.2114.8118.0912.31
61247[M]+, 147(100), 119(75)1934----------
62276[M]+, 108(100), 79(26)1938----------
63276[M]+, 108(100), 79(35)1951----------
64272[M]+, 81(100), 161(75)1955----------
65217[M]+, 108(100), 79(50)1989----------
66230[M]+, 108(100), 79(35)2051----------
Total 97.7498.1098.4698.7497.5098.5597.9798.8898.2797.76
% Identified 94.1693.2195.0694.0994.5391.4090.4193.1692.7690.41
Including:
Aliphatics 7.788.965.355.254.587.304.764.734.324.07
Aromatics 0.000.000.000.000.000.000.000.000.000.00
Monoterpene hydrocarbons 0.390.100.190.210.510.110.390.120.440.23
Sesquiterpene hydrocarbons 6.984.937.329.916.223.432.615.594.765.97
Oxygenated sesquiterpenoids 79.0179.2282.2078.7283.2280.5682.6582.7283.2480.14
- under 0.01%. a Retention index on Quadex 007-5MS column. b For abbreviations of samples see Table 1.
Table
Table 3. Volatile compounds detected in the analyzed samples of genetic lineage C2 and cryptic species I of the A. pinguis.
Table 3. Volatile compounds detected in the analyzed samples of genetic lineage C2 and cryptic species I of the A. pinguis.
No.CompoundsRI aCode b
C2-1C2-2C2-3C2-4I-1I-2I-3I-4I-5I-6
11-Penten-3-ol6730.090.090.090.08------
2Pentanal677----0.180.320.210.110.290.12
3(Z)-2-Penten-1-ol7660.090.100.080.110.110.210.060.120.220.07
4Hexanal7730.790.830.630.651.491.120.911.281.640.72
5(Z)-3-Hexen-1-ol8581.631.791.221.670.521.010.630.920.710.69
61-Hexanol8673.313.234.223.855.816.525.928.416.234.39
7α-Pinene936----0.120.080.110.090.090.10
8Camphene953----0.070.120.040.120.320.19
9Benzaldehyde970----------
10β-Pinene9780.290.370.320.390.210.310.410.200.490.11
11δ-Elemene1324----------
12α-Longipinene13500.150.120.130.150.090.100.120.170.130.11
13α-Ylangene13730.110.080.090.100.320.110.310.230.320.29
14α-Copaene1376----0.100.080.070.110.120.11
15Sativene13960.430.490.230.510.200.220.180.210.220.21
16β-Caryophyllene14150.260.230.490.380.040.110.230.110.130.23
17Longifolene14170.510.470.620.570.310.300.420.210.200.17
18β-Ylangene14230.640.690.590.610.700.510.680.540.610.63
19Cedrene14273.413.472.213.390.320.410.710.530.490.38
20204[M]+, 161 (100), 105(85)1431----0.100.110.120.130.110.09
21Thujopsene14350.090.130.090.120.080.060.090.060.090.11
22α-Guaiene1439----0.310.320.400.580.320.31
23204[M]+, 93(100), 81(82)1441----1.210.731.070.670.830.92
24204[M]+, 93(100), 79(85)1443----0.040.060.050.070.060.05
25204[M]+, 119(100), 93(75)14450.160.120.220.140.060.050.070.060.040.05
26α-Himachalene14470.090.110.120.080.230.110.200.110.080.17
27204[M]+, 91(100), 105(93)14530.320.370.300.410.590.820.440.720.890.59
28Alloaromadendrene14570.270.320.090.332.611.732.231.542.531.81
29γ-Gurjunene14700.090.120.390.180.100.030.070.090.110.21
30β-Himachalene1500----0.120.090.050.060.110.23
31204[M]+, 119(100), 91(70)15030.120.100.060.090.130.230.120.230.110.22
32Cuparene1505----0.230.320.340.270.260.42
33δ-Cadinene1517----0.200.090.220.130.210.17
34β-Sesquiphellandrene15200.050.060.040.030.080.040.050.080.060.11
35204[M]+, 119(100), 91(66)1524----------
36204[M]+, 69(100), 91(38)1530----4.614.895.294.524.715.92
37216[M]+, 109(100), 145(75)15331.181.221.321.273.212.604.381.922.493.32
38α-Copaene-11-ol1540----0.190.430.410.390.200.21
39Longicamphenylone1559----0.120.190.320.110.120.11
40Deoxopinguisone15633.593.624.423.985.605.125.545.325.615.68
41220[M]+, 91(100), 110(90)1585----0.110.220.230.120.100.09
42204[M]+, 137(100), 81(60)1593----0.090.120.110.050.040.08
43218[M]+, 91(100), 119(57)16036.286.336.996.590.060.050.070.110.060.05
44220[M]+, 135(100), 91(60)1620 ---6.424.616.694.294.834.52
45220[M]+, 110(100), 91(97)1626 ---0.110.100.060.050.040.11
46220[M]+, 91(100), 79(82)16330.100.090.110.120.050.110.210.120.090.10
47Longiverbenone1641----1.701.701.601.201.501.90
48δ-Cadinol1646----------
49Aromadendreneoxide-(2)1678----0.110.100.040.120.050.09
50222[M]+, 95(100), 81(75)16850.190.220.200.252.902.432.893.714.324.81
51220[M]+, 81(100), 67(90)16870.490.530.120.420.890.910.600.410.400.89
52Pinguisone170571.9271.8069.2969.0643.5945.2243.9144.6943.7143.90
53Isopinguisone1712----0.110.050.040.120.200.09
54Bryopterin A1735----0.050.090.050.080.110.12
55Dihydrobryopterin A17550.270.300.230.260.690.320.510.480.320.51
56Methyl norpinguisonate1791----0.200.210.190.390.220.19
57236[M]+, 95(100), 109(85)1846----------
58244[M]+, 189(100), 105(15)1851----------
59246[M]+, 192(100), 91(43)1882----1.902.111.992.082.412.12
60Costunolide19141.441.492.891.513.825.911.804.303.593.85
61247[M]+, 147(100), 119(75)1934----0.330.420.690.440.330.42
62276[M]+, 108(100), 79(26)1938----------
63276[M]+, 108(100), 79(35)1951----------
64272[M]+, 81(100), 161(75)1955----1.391.411.621.741.541.70
65217[M]+, 108(100), 79(50)1989----------
66230[M]+, 108(100), 79(35)2051----2.402.522.612.592.712.33
Total 98.3698.8997.8097.3097.3398.1698.3897.5197.7297.09
% Identified 89.5289.9188.4888.0170.7373.6669.0773.4871.6168.71
Including:
Aliphatics 5.916.046.246.368.119.187.7310.849.095.99
Aromatics 0.000.000.000.000.000.000.000.000.000.00
Monoterpene hydrocarbons 0.290.370.320.390.400.510.560.410.900.40
Sesquiterpene hydrocarbons 6.106.295.096.456.044.636.375.035.995.67
Oxygenated sesquiterpenoids 77.2277.2176.8374.8156.1859.3454.4157.2055.6356.65
- under 0.01%. a Retention index on Quadex 007-5MS column. b For abbreviations of samples see Table 1.
Table
Table 4. Volatile compounds detected in the analyzed samples of cryptic species E (genetic lineage E1 and E2) of the A. pinguis.
Table 4. Volatile compounds detected in the analyzed samples of cryptic species E (genetic lineage E1 and E2) of the A. pinguis.
No.CompoundsRI aCode b
E1-1E1-2E1-3E1-4E1-5E2-1E2-2E2-3E2-4
11-Penten-3-ol6730.110.120.230.120.040.990.610.700.87
2Pentanal677---------
3(Z)-2-Penten-1-ol7660.060.120.060.120.060.410.390.450.37
4Hexanal7730.120.130.090.210.321.020.920.971.09
5(Z)-3-Hexen-1-ol8580.410.520.070.320.411.591.411.451.53
61-Hexanol8670.920.910.620.691.331.991.912.021.95
7α-Pinene9360.330.060.520.130.110.630.790.590.83
8Camphene9530.060.410.110.100.120.090.100.080.09
9Benzaldehyde970---------
10β-Pinene9780.090.210.070.120.110.320.220.370.25
11δ-Elemene1324---------
12α-Longipinene13500.220.050.040.060.110.060.060.040.09
13α-Ylangene13730.110.120.320.080.190.060.070.070.08
14α-Copaene13760.100.050.070.040.210.110.090.070.13
15Sativene13960.921.281.411.211.071.320.791.211.26
16β-Caryophyllene14150.220.110.090.100.190.170.420.260.37
17Longifolene14173.513.794.124.224.311.020.830.920.86
18β-Ylangene14235.303.084.483.714.820.500.480.430.53
19Cedrene14271.721.521.481.311.420.110.110.090.07
20204[M]+, 161 (100), 105(85)14310.410.210.280.170.520.730.510.640.57
21Thujopsene14351.831.602.812.272.530.881.081.140.97
22α-Guaiene14390.491.170.770.620.421.090.890.920.94
23204[M]+, 93(100), 81(82)14417.197.696.897.888.431.631.841.731.91
24204[M]+, 93(100), 79(85)14430.490.080.380.080.090.220.120.260.18
25204[M]+, 119(100), 93(75)14451.720.811.231.721.500.080.090.070.06
26α-Himachalene14471.982.811.822.512.830.190.420.230.31
27204[M]+, 91(100), 105(93)1453-----0.510.920.850.62
28Alloaromadendrene145710.5111.2211.6910.7210.220.130.310.180.34
29γ-Gurjunene1470-----0.190.180.150.23
30β-Himachalene15005.696.724.916.426.430.090.090.080.07
31204[M]+, 119(100), 91(70)15030.690.510.801.080.990.080.090.090.11
32Cuparene15051.200.911.311.900.710.100.110.070.13
33δ-Cadinene15170.290.220.510.180.320.310.300.340.27
34β-Sesquiphellandrene15200.200.110.300.110.330.100.110.070.09
35204[M]+, 119(100), 91(66)15240.180.200.220.190.29----
36204[M]+, 69(100), 91(38)15300.720.800.480.410.830.110.100.130.09
37216[M]+, 109(100), 145(75)15330.190.230.290.300.320.330.530.580.41
38α-Copaene-11-ol15400.040.080.070.410.110.060.050.030.05
39Longicamphenylone15591.222.311.471.020.790.200.300.240.29
40Deoxopinguisone15639.117.926.527.006.7222.6124.6023.8622.37
41220[M]+, 91(100), 110(90)15850.090.600.420.730.44----
42204[M]+, 137(100), 81(60)15931.110.871.200.931.110.090.080.090.07
43218[M]+, 91(100), 119(57)16031.531.421.281.831.33----
44220[M]+, 135(100), 91(60)16205.105.375.236.315.880.310.190.340.28
45220[M]+, 110(100), 91(97)16260.110.090.100.230.290.110.400.360.19
46220[M]+, 91(100), 79(82)16332.291.801.732.092.200.070.190.110.21
47Longiverbenone16411.191.331.901.931.620.520.880.790.64
48δ-Cadinol1646---------
49Aromadendreneoxide-(2)16782.602.872.812.332.410.090.200.150.19
50222[M]+, 95(100), 81(75)16852.562.072.692.932.720.410.310.270.39
51220[M]+, 81(100), 67(90)16871.420.711.980.810.580.110.210.170.09
52Pinguisone17058.4411.959.087.897.0735.4231.0832.5933.63
53Isopinguisone17124.523.523.413.203.736.425.605.826.14
54Bryopterin A17350.120.190.060.100.414.084.283.894.18
55Dihydrobryopterin A17554.324.514.925.424.299.8910.0110.8510.19
56Methyl norpinguisonate17912.411.821.931.721.700.190.080.120.07
57236[M]+, 95(100), 109(85)1846---------
58244[M]+, 189(100), 105(15)1851---------
59246[M]+, 192(100), 91(43)1882---------
60Costunolide1914---------
61247[M]+, 147(100), 119(75)1934---------
62276[M]+, 108(100), 79(26)19380.050.110.120.050.090.110.100.090.08
63276[M]+, 108(100), 79(35)19510.910.791.421.431.620.400.410.290.34
64272[M]+, 81(100), 161(75)19550.040.030.050.210.080.110.110.120.09
65217[M]+, 108(100), 79(50)19890.400.520.370.380.400.420.710.340.64
66230[M]+, 108(100), 79(35)20510.180.190.420.210.430.110.490.210.13
Total 97.7498.8497.6598.2697.6098.8997.1797.9897.93
% Identified 70.3673.7470.0768.2967.4692.9589.7791.2491.47
Including:
Aliphatics 1.621.801.071.462.166.005.245.595.81
Aromatics 0.000.000.000.000.000.000.000.000.00
Monoterpene hydrocarbons 0.480.680.700.350.341.041.111.041.17
Sesquiterpene hydrocarbons 34.2934.7636.1335.4636.116.436.346.276.74
Oxygenated sesquiterpenoids 33.9736.5032.1731.0228.8579.4877.0878.3477.75
- under 0.01%. a Retention index on Quadex 007-5MS column. b For abbreviations of samples see Table 1.
Table
Table 5. Volatile compounds detected in the analyzed samples of cryptic species G and H of the A. pinguis.
Table 5. Volatile compounds detected in the analyzed samples of cryptic species G and H of the A. pinguis.
No.CompoundsRI aCode b
G-1G-2G-3G-4H-1H-2H-3H-4
11-Penten-3-ol6730.040.050.060.060.050.050.060.04
2Pentanal6770.110.080.100.090.080.080.090.11
3(Z)-2-Penten-1-ol766--------
4Hexanal7730.230.150.170.120.230.190.210.25
5(Z)-3-Hexen-1-ol8580.300.070.110.090.130.110.220.09
61-Hexanol8670.891.011.071.191.551.511.421.48
7α-Pinene9360.210.150.140.110.100.120.080.09
8Camphene9530.120.060.090.070.060.060.050.03
9Benzaldehyde970--------
10β-Pinene9780.790.720.590.610.410.440.520.48
11δ-Elemene1324--------
12α-Longipinene13500.310.470.520.590.630.600.410.56
13α-Ylangene13730.110.070.040.050.150.130.090.08
14α-Copaene13760.510.470.390.410.440.420.430.47
15Sativene13960.510.590.650.620.760.730.640.68
16β-Caryophyllene14150.340.370.450.420.180.240.360.27
17Longifolene14171.271.251.191.231.211.320.991.19
18β-Ylangene14231.211.441.551.531.571.621.111.23
19Cedrene14270.110.140.100.120.080.080.090.07
20204[M]+, 161 (100), 105(85)14310.720.830.720.810.910.931.010.96
21Thujopsene14351.691.821.731.932.322.371.692.09
22α-Guaiene14390.210.220.160.180.180.220.090.15
23204[M]+, 93(100), 81(82)14410.230.190.160.140.250.230.120.19
24204[M]+, 93(100), 79(85)14430.210.140.110.120.200.220.130.21
25204[M]+, 119(100), 93(75)14450.110.080.110.090.150.120.130.14
26α-Himachalene14470.120.240.270.330.280.310.220.24
27204[M]+, 91(100), 105(93)14531.071.441.521.651.611.581.831.78
28Alloaromadendrene14571.401.231.181.111.141.121.321.08
29γ-Gurjunene14700.480.510.390.420.410.380.390.45
30β-Himachalene15000.210.220.170.190.190.210.090.13
31204[M]+, 119(100), 91(70)15031.191.010.930.990.981.101.040.14
32Cuparene15051.371.411.321.291.971.931.421.57
33δ-Cadinene15170.110.180.160.210.180.100.700.49
34β-Sesquiphellandrene15200.090.150.190.200.050.050.070.03
35204[M]+, 119(100), 91(66)1524--------
36204[M]+, 69(100), 91(38)15300.120.110.080.090.080.110.060.12
37216[M]+, 109(100), 145(75)15332.622.432.512.321.691.791.381.63
38α-Copaene-11-ol15400.220.250.310.290.130.110.120.10
39Longicamphenylone15590.290.330.370.420.170.220.320.26
40Deoxopinguisone15638.998.828.928.718.278.228.318.08
41220[M]+, 91(100), 110(90)15850.110.090.150.120.160.210.090.08
42204[M]+, 137(100), 81(60)1593--------
43218[M]+, 91(100), 119(57)16030.320.240.180.210.360.420.220.26
44220[M]+, 135(100), 91(60)16200.490.470.390.420.910.800.421.01
45220[M]+, 110(100), 91(97)16260.220.120.110.090.130.100.090.07
46220[M]+, 91(100), 79(82)16330.080.070.140.110.080.120.090.07
47Longiverbenone1641--------
48δ-Cadinol16461.721.771.861.821.711.691.521.58
49Aromadendreneoxide-(2)1678--------
50222[M]+, 95(100), 81(75)16850.320.240.270.220.370.410.320.43
51220[M]+, 81(100), 67(90)16873.111.831.781.722.012.411.791.93
52Pinguisone170552.1253.9854.2154.3856.4155.5057.2956.43
53Isopinguisone1712- - ---
54Bryopterin A17350.190.180.220.200.070.090.100.14
55Dihydrobryopterin A17553.104.014.744.823.513.613.693.44
56Methyl norpinguisonate17910.801.321.271.291.201.141.431.09
57236[M]+, 95(100), 109(85)1846--------
58244[M]+, 189(100), 105(15)1851--------
59246[M]+, 192(100), 91(43)18820.090.070.090.100.080.110.120.15
60Costunolide19142.032.892.973.082.122.063.502.73
61247[M]+, 147(100), 119(75)19340.120.170.190.170.250.220.210.31
62276[M]+, 108(100), 79(26)1938--------
63276[M]+, 108(100), 79(35)1951--------
64272[M]+, 81(100), 161(75)1955--------
65217[M]+, 108(100), 79(50)1989--------
66230[M]+, 108(100), 79(35)20510.040.050.070.060.240.210.140.16
Total 93.3796.2097.1797.6198.4098.1298.2396.84
% Identified 82.2086.6287.6688.1887.9487.0389.0487.20
Including:
Aliphatics 1.571.511.361.552.041.942.001.97
Aromatics 0.000.000.000.000.000.000.000.00
Monoterpene hydrocarbons 1.120.930.820.790.570.620.650.60
Sesquiterpene hydrocarbons 10.0510.7810.4610.8311.7411.8310.1110.78
Oxygenated sesquiterpenoids 69.4673.5574.8775.0173.5972.6476.2873.85
- under 0.01%. a Retention index on Quadex 007-5MS column. b For abbreviations of samples see Table 1.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Wawrzyniak, R.; Wasiak, W.; Jasiewicz, B.; Bączkiewicz, A.; Buczkowska, K. Chemical Fingerprinting of Cryptic Species and Genetic Lineages of Aneura pinguis (L.) Dumort. (Marchantiophyta, Metzgeriidae). Molecules 2021, 26, 1180. https://doi.org/10.3390/molecules26041180

AMA Style

Wawrzyniak R, Wasiak W, Jasiewicz B, Bączkiewicz A, Buczkowska K. Chemical Fingerprinting of Cryptic Species and Genetic Lineages of Aneura pinguis (L.) Dumort. (Marchantiophyta, Metzgeriidae). Molecules. 2021; 26(4):1180. https://doi.org/10.3390/molecules26041180

Chicago/Turabian Style

Wawrzyniak, Rafał, Wiesław Wasiak, Beata Jasiewicz, Alina Bączkiewicz, and Katarzyna Buczkowska. 2021. "Chemical Fingerprinting of Cryptic Species and Genetic Lineages of Aneura pinguis (L.) Dumort. (Marchantiophyta, Metzgeriidae)" Molecules 26, no. 4: 1180. https://doi.org/10.3390/molecules26041180

Article Metrics

Back to TopTop