Skip to main content
Scientific Reports logoLink to Scientific Reports
. 2018 Aug 6;8:11730. doi: 10.1038/s41598-018-30156-8

Identification of saturated and unsaturated 1-methoxyalkanes from the Thai millipede Orthomorpha communis as potential “Raincoat Compounds”

Aem Nuylert 1,2, Yasumasa Kuwahara 1, Tipparat Hongpattarakere 3, Yasuhisa Asano 1,2,
PMCID: PMC6079017  PMID: 30082895

Abstract

Mixtures of saturated and unsaturated 1-methoxyalkanes (alkyl methyl ethers, representing more than 45.4% of the millipede hexane extracts) were newly identified from the Thai polydesmid millipede, Orthomorpha communis, in addition to well-known polydesmid defense allomones (benzaldehyde, benzoyl cyanide, benzoic acid, mandelonitrile, and mandelonitrile benzoate) and phenolics (phenol, o- and p-cresol, 2-methoxyphenol, 2-methoxy-5-methylphenol and 3-methoxy-4-methylphenol). The major compound was 1-methoxy-n-hexadecane (32.9%), and the mixture might function as “raincoat compounds” for the species to keep off water penetration and also to prevent desiccation.

Introduction

Certain arthropods are well known to produce exocrine secretions which serve a variety of functions such as defense against predators1, antimicrobial and antifungal activities2, protection against moisture3, and intraspecific information pheromones46. Millipedes (Diplopoda) belonging to seven of the 16 orders (composed of 145 families, over 12,000 species described) possess exocrine glands (repugnatory glands or ozadenes, located on the pleurotergites) and the chemical compositions of their secretions have been studied for more than 140 species710. Among them, 58 species of Polydesmida have been examined worldwide and their defense allomone compositions have been well documented79. Most polydesmid species are cyanogenic, and their defense components are mainly produced by two enzymes [hydroxynitrile lyase (HNL)11 and mandelonitrile oxidase (MOX)12] from a mandelonitrile substrate stored in the reservoir of repugnatory glands. HNL is responsible for the production of HCN and benzaldehyde, which is further reduced to benzyl alcohol or oxidized to benzoic acid. MOX is responsible for the oxidation of mandelonitrile into benzoyl cyanide and the production of hydrogen peroxide as a by-product13. Benzoyl cyanide reacts chemically with mandelonitrile to give mandelonitrile benzoate14, and also with water to produce benzoic acid and HCN. Polydesmida also contains non-cyanogenic species, Eutrichodesmus elegans and E. armatus, whose defensive allomones have been identified as (Z)- and (E)-2-nitroethenylbenzene and 2-nitroethylbenzene15,16. Those nitro compounds are also known to be derived from L-phenylalanine, the same precursor of mandelonitrile15.

Contrary to Insecta where they have been well documented3, no waxy compounds, such as hydrocarbons and fatty acid esters, have ever been described as agents for possible protection against moisture and desiccation among most of the Diplopoda5,6. They occur on all continents (except Antarctica) and in nearly all terrestrial environments from the temperate to the tropical zones17, and only some species of millipedes (mentioned later) belonging to Julida have been known to possess certain fatty acid esters, presumably as cuticular lipids.

The Thai millipede Orthomorpha communis Likhitrakarn, Golovatch & Panha, 2011 (Paradoxosomatidae: Polydesmida) is distributed widely in the eastern part of Thailand close to the border with Cambodia and has newly been found in Hat Yai District, Songkhla Province, Thailand. The live coloration of blackish-brown body rings, with paraterga and epiproct showing a distinctive creamy yellow during contracting (Fig. 1).

Figure 1.

Figure 1

Picture of the Thai millipede O. communis.

Using gas chromatography coupled with mass spectrometry (GC/MS) analysis of the species, we happened to detect a series of saturated and unsaturated wax-like components, other than the conventional mixtures derived from mandelonitrile. These wax-like components have not been reported in other millipedes, and our hypothesis is that they have a function similar to the “raincoat” found in the oribatid mite, Liacarus subterraneus (Acari: Oribatida). This mite secretes di-glycerides via an esterification reaction between fatty acids and glycerin5. As a result, the chemical structures of these saturated and unsaturated wax-like components was investigated.

Results

GC/MS analyses of the Thai millipede

As shown in Fig. 2, the GC-profile showed a total of 31 peaks (=compounds) including non-resolved components [2-methoxyphenol (5) and benzoyl cyanide (6), as mentioned later].

Figure 2.

Figure 2

GC profile of the hexane extract from the Thai millipede O. communis. 1–10 and 26; components known as defensive allomone of polydesmid millipedes, 11–25 and 27–31; waxy compounds. Structure and names see Fig. 4 and Table 1.

Mass spectra of all peaks are summarized in Table 1, including identified results by co-chromatography with authentic compounds and (or) elucidated structures, as mentioned later.

Table 1.

Gas chromatographic and mass spectral data of compounds from extracts of the Thai millipede, O. communis.

Peak no. Retention Content Mass spectrometric fragmentation (m/z) Compound identified
time index* (%) as Standard obtained (Library ID %)
1 5.838 959 26.8 106 (M+, 100), 105 (96), 77 (90), 51 (32) benzaldehyde com. (97%)
2 5.972 970 3.1 94 (M+, 100), 66 (30.4) phenol com. (91%)
3 7.185 1068 0.1 108 (M+, 100), 107 (87), 90 (21), 89 (13), 80 (11), 79 (28), 77 (27) o-cresol com.
4 7.512 1094 0.6 108 (M+, 81), 107 (100), 90 (7), 79 (20), 77 (22) p-cresol com. (96%)
5 7.819 1118 0.2 124 (M+, 94), 109 (100), 81 (44), 65 (5), 53 (15) **2-methoxyphenol com. (96%)
6 7.822 1119 14.9 131 (M+, 72), 105 (100), 77 (55), 74 (8), 51 (23) benzoyl cyanide com. (93%)
7 8.982 1213 6.0 122 (M+, 85), 105 (100), 77 (72), 51 (35) benzoic acid com. (96%)
8 9.340 1242 0.1 138 (M+, 77), 123 (100), 95 (25), 77 (12), 67 (21), 55 (11), 51 (9) 2-methoxy-5-methylphenol com. (94%)
9 9.405 1247 0.5 138 (M+, 96), 123 (100), 95 (26), 77 (8), 67 (13), 55 (10), 51 (8) 3-methoxy-4-methylphenol 94%
10 11.225 1394 trace 133 (M+, 70), 115 (39), 105 (100), 77 (95), 51 (45) mandelonitrile com. (90%)
11 15.203 1716 0.3 196 (M+−32, 26), 168 (15), 140 (8), 125 (20), 111 (39), 97 (72), 83 (92), 69 (71), 55 (60), 45 (100) 1-methoxy-n-tetradecane syn. (90%)
12 15.930 1775 0.3 210 (M+−32, 20), 195 (4), 182 (18), 167 (3), 154 (19), 139 (6), 125 (15), 111 (40), 97 (70), 83 (92), 69 (90), 56 (96), 45 (100) 1-methoxy-13-methyl-tetradecane
13 16.341 1808 0.5 210 (M+−32, 25), 182 (13), 154 (6), 140 (8), 125 (21), 111 (46), 97 (81), 83 (100), 69 (73), 55 (61), 45 (98) 1-methoxy-n-pentadecane
14 17.033 1864 0.5 224 (M+−32, 11), 209 (2), 196 (9), 181 (3), 168 (8), 153 (5), 140 (12), 125 (18), 111 (49), 97 (72), 83 (100), 69 (95), 55 (94), 45 (97) 1-methoxy-14-methylpentadecane
15 17.159 1874 0.5 254 (M+, 2), 222 (10), 194 (2), 180 (1), 166 (2), 152 (2), 137 (6), 123 (12), 109 (31), 96 (62), 82 (100), 67 (73), 55 (47), 45 (39) 1-methoxy-n-hexadecene
16 17.203 1878 1.0 254 (M+, 2), 222 (14), 194 (3), 179 (1), 166 (3), 152 (3), 137 (8), 123 (16), 109 (30), 96 (71), 82 (100), 67 (59), 55 (61), 45 (45) 1-methoxy-Z−9-hexadecene syn
17 17.300 1885 0.7 254 (M+, 2), 222 (11), 194 (2), 180 (1), 166 (2), 152 (3), 137 (7), 123 (14), 109 (27), 96 (74), 82 (100), 67 (54), 55 (78), 45 (49) 1-methoxy-E−9-hexadecene
18 17.466 1899 32.9 224 (M+−32, 31), 213 (1), 196 (15), 182 (2), 168 (5), 154 (7), 139 (10), 125 (27), 111 (53), 97 (88), 83 (100), 69 (69), 55 (59), 45 (86) 1-methoxy-n-hexadecane syn. (91%)
19 17.832 1928 0.2 268 (M+, 2), 236 (16), 208 (3), 194 (1), 180 (2), 166 (1), 152 (3), 137 (9), 123 (19), 109 (34), 96 (66), 82 (100), 67 (54), 55 (55), 45 (42) 1-methoxy-Z-9-15-methyl-hexadecene
20 17.872 1932 0.4 238 (M+−32, 2), 223 (1), 210 (2), 196 (1), 182 (1), 169 (9), 153 (22), 140 (11), 125 (44), 111 (66), 97 (94), 83 (93), 71 (89), 69 (65), 57 (100), 45 (68) 1-methoxy-methyl-hexadecane
21 18.082 1948 1.1 238 (M+−32, 13), 223 (2), 210 (11), 195 (3), 182 (10), 168 (2), 154 (6), 139 (5), 125 (14), 111 (37), 97 (57), 83 (100), 69 (74), 57 (78), 45 (80) 1-methoxy-15- methylhexadecane
22 18.166 1955 0.3 238 (M+−32, 5), 227 (1), 209 (15), 181 (7), 168 (4), 153 (6), 139 (12), 125 (28), 111 (44), 97 (80), 83 (83), 70 (100), 57 (62), 55 (56), 45 (66) 1-methoxy-14-methylhexadecane
23 18.220 1960 0.3 268 (M+, 2), 236 (13), 208 (2), 194 (1), 180 (2), 166 (2), 152 (3), 137 (9), 123 (16), 109 (31), 96 (72), 82 (100), 67 (56), 55 (56), 45 (37) 1-methoxy-Z-9-heptadecene syn.
24 18.295 1966 0.2 268 (M+, 2), 236 (7), 208 (3), 193 (2), 180 (3), 166 (3), 151 (5), 137 (9), 123 (17), 109 (32), 96 (72), 82 (100), 67 (59), 55 (68), 45 (48) 1-methoxy-E-9-heptadecene
25 18.454 1979 0.4 238 (M+−32, 20), 227 (1), 210 (10), 196 (1), 182 (4), 168 (4), 154 (5), 139 (8), 125 (24), 111 (48), 97 (85), 83 (100), 69 (68), 57 (56), 45 (82) 1-methoxy-n-heptadecane
26 18.530 1985 2.3 237 (M+, 17), 116 (39), 105 (100), 89 (11), 77 (25), 51 (11) mandelonitrile benzoate prepd. (80%)
27 19.126 2033 1.2 280 (M+, 2), 248 (3), 219 (1), 205 (1), 191 (1), 184 (3), 177 (2), 163 (4), 152 (9), 149 (9), 135 (25), 121 (30), 109 (30), 95 (69), 81 (89), 67 (100), 55 (51), 45 (47) 1-methoxy-Z,Z-9,12-octadecadiene syn.
28 19.195 2038 3.2 282 (M+, 2), 250 (12), 222 (2), 208 (1), 194 (2), 180 (1), 166 (2), 152 (3), 137 (9), 123 (16), 109 (29), 96 (70), 82 (100), 67 (54), 55 (54), 45 (37) 1-methoxy-Z-9-octadecene syn. (99%)
29 19.241 2042 0.8 282 (M+, 3), 250 (14), 239 (1), 222 (2), 208 (1), 194 (2), 180 (2), 165 (2), 152 (4), 137 (10), 123 (18), 109 (31), 96 (80), 82 (100), 69 (49), 55 (58), 45 (38) 1-methoxy-E-9-octadecene
30 19.438 2058 0.4 252 (M+−32, 19), 241 (1), 224 (8), 210 (1), 196 (3), 182 (3), 168 (4), 154 (5), 139 (9), 125 (26), 111 (49), 97 (86), 83 (100), 69 (68), 57 (58), 45 (78) 1-methoxy-n-octadecane syn.
31 20.251 2124 0.1 296 (M+, 1), 264 (5), 236 (2), 222 (1), 208 (2), 194 (1), 180 (2), 165 (2), 151 (4), 137 (9), 123 (16), 109 (28), 96 (71), 82 (100), 69 (55), 55 (70), 45 (45) 1-methoxy-Z-9-nonadecene

*Retention index; caluculated by HP-5 column under conditions described in text, as reported (Kovat. 1958),

**Detectable by selected ion chromatography com.; commercially avilable, syn.; prepared from palm oil, prepd; by synthesis.

A total of 20 peaks (11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 27, 28, 29, 30, and 31, 45.4%) were newly detected in the present species and represented the first discovery of the hereafter named “waxy compounds” among Polydesmida. Their structures were later elucidated as 1-methoxyalkanes by (1) column chromatography (SiO2) behavior, (2) NMR analysis, and (3) GC-mass spectra (the presence of M+ or M+-32, and m/z 45), using 1-methoxyalkanes prepared from palm oil as an authentic compound.

Chromatographic behavior of waxy compounds on SiO2 column

When the hexane extracts from seven adult millipedes were separated by silica gel column (300 mg, 0.5ϕ × 2.1 cm) chromatography, most of the waxy compounds were recovered in the fraction (3 ml) eluted with the 1% Et2O in hexane, indicating their non-polar nature (less polar than esters). Methyl ether mixtures prepared from palm oil were also recovered in the same 1% Et2O in hexane fractions, as mentioned above. Peak 1 was eluted by 2% Et2O in hexane (3 ml) with the remaining waxy compounds. As shown in Fig. 3, peaks 11, 18, 27, 28, and 30 derived from the palm oil were identical to those derived from millipedes using GC tRs and mass spectra (mentioned below).

Figure 3.

Figure 3

Comparison of GC profiles. (A) from Thai millipedes, and (B) 1-methoxyalkanes prepared from palm oil. Structure and names, see Fig. 4 and Table 1.

1H-NMR spectrum of the waxy compounds from millipedes and 1-methoxyalkanes from palm oil

The NMR spectrum of millipede compounds after being purified by the SiO2 column proved to be almost the same as the spectra for the 1-methoxyalkanes found in palm oil, except for a difference in the integral on long chain methylenes. The following chemical shifts were observed for millipedes; ω-methyl (3H, t, J = 6.6 Hz at δ 0.88 ppm), long chain methylenes (26H, m at δ 1.52–1.60 ppm), -CH2-CH2-O- (2H, m, at δ 1.52–1.60 ppm), CH3-O- (3H, s, at δ 3.33 ppm), and -CH2-CH2-O (2H, t, J = 6.6 Hz at δ 3.36 ppm), thus, identifying the structure as 1-methoxy-hexadecane. As a result, waxy components from millipede were shown to be a mixture of saturated and unsaturated 1-methoxyalkanes.

GC/MS analysis of standard 1-methoxyalkanes prepared from palm oil

Peaks 11, 18, 27, 28, and 30 in the preparation from the palm oil showed the same GC-retention times and mass spectra to those from millipedes (this corresponded to 84.4% of the waxy composition in the millipede). Among them, significant results (more than 90% identities) of library search results were available for peaks 11 (90%), 18 (91%) and 28 (99%). As a result, structures of peaks 11, 18, and 28 were identified as 1-methoxy-n-tetradecane (11), 1-methoxy-n-hexadecane (18) and 1-methoxy-Z-9-octadecene (28), respectively (Fig. 4).

Figure 4.

Figure 4

Chemical structures identified or elucidated in the hexane extract of the Thai millipede O. communis. (a) Compounds commonly detectable among polydesmid millipedes as defense allomone, (b) 1-methoxyalkanes, newly detected in the species.

Based on the above results, the other two peaks 27 and 30 were thought to be similar to the 1-methoxyalkanes originated from the fatty acid compositions of the palm oil, and described as 1-methoxy-Z,Z-9,12-octadecadiene (27) and 1-methoxy-n-octadecane (30) by mass spectra analysis (Table 1, mentioned later).

Structure elucidation of waxy compounds by GC/MS

Mass spectra of waxy compounds mostly indicated alkene series of fragment ions with sigmoid intensity from m/z 41 to m/z 139 or m/z 153. The fragment ion at m/z 45 (-CH2+-OMe) was always observable in all compounds, indicating the presence of oxygen in the molecule. Saturated compounds (11, 12, 13, 14, 18, 20, 21, 22, 25, and 30, except 20 and 22) displayed each reliable intensity (more than 11%) of fragment at m/z M+-32(MeOH) with trace intensity fragment at M+-1, but no M+ ion, and m/z 83 was constantly observable as the base ion peak, respectively. On the other hand, in the case of monoene compounds (15, 16, 17, 19, 23, 24, 28, 29, and 31), M+ ions were detected with M+-32(MeOH) and the base ion at m/z 82. In the case of dienoic compound (27), the base ion was observed at m/z 67. As a whole, these facts implied that elimination of CH3-OH or H+ could occur in all those components, and each compound was elucidated as 1-methoxyalkane (11, 12, 13, 14, 18, 20, 21, 22, 25, and 30), 1-methoxyalkene (15, 16, 17, 19, 23, 24, 28, 29, and 31), or 1-methoxyalkadiene (27) (Table 1).

Structure elucidation of 1-methoxyalkanes in the millipede

Mass spectra of 13 and 25 were identical to those of 11 [M+-32(MeOH) ions at m/z 196], 18 [M+-32(MeOH) ions at m/z 224] and 30 [M+-32(MeOH) ions at m/z 252] derived from palm oil reduction, except M+-32(MeOH) ions observed at m/z 210 and 238. Therefore, peak 13 was described as 1-methoxy-n-pentadecane (13) and peak 25 as 1-methoxy-n-heptadecane (25) (Table 1, Fig. 4).

Peaks 12, 14, 20, 21, and 22 indicated M+-32 (MeOH) ions at m/z 210, m/z 224, m/z 238, m/z 238, and m/z 238 as the largest fragments, respectively, and these were thought to be 1-methoxy-methyl-branched (substituted) alkanes. Differences on Kovat’s retention indexes (∆KI between 1-methoxy-n-alkane and 1-methoxy-methyl substituted alkane = increment of additional methyl residue) were calculated as follows; KI of peak 12 (1775) was that of peak 11 (1716) + ∆KI 59, likewise ∆KI 56 for peak 14, ∆KI 33 for peak 20, ∆KI 49 for peak 21 and ∆KI 56 for peak 22. If we assume peak 12 and peak 14 are 1-methoxy-13-methyltetradecane (12, iso-C15 ether, ∆KI 59) and 1-methoxy-14-methylpentadecane (14, iso-C16 ether, ∆KI 56), respectively, peak 21 (∆KI 49) or 22 (∆KI 56) should be 1-methoxy-15-methylhexadecane (21, iso-C17 ether), while peak 20 (∆KI 33) remained obscure as a branched C17-OMe. If ∆KI′ is compared between n- and iso-alkyl series, ∆KI′ between peaks 12 and 13 was observed as 33, likewise between peaks 14 and 18 as 35, and between peaks 21 and 25 as 31, then 21 was more likely a 1-methoxy-15-methylhexadecane (21, iso-C17 ether), because ∆KI′ between peaks 22 and 25 was 24. On the other hand, mass fragment M+-32 (MeOH)-15 (CH3) ion was observed in peaks 12 (4%), 14 (2%), 20 (1%), 21(2%) and 22 (1%) suggested the presence of methyl residue in the molecule, while peak 22 gave strong M+-32 (MeOH)-29 (CH3CH2) ion (18%), indicative of a removable ethyl residue (ante-iso carbon chains) in the structure. As a whole, peaks 12, 14, and 21 should be proposed as 1-methoxy-iso-alkanes; 1-methoxy-13-methyltetradecane (12, iso-pentadecyl methyl ether), 1-methoxy-14-methylpentadecane (14, iso-hexadecyl methyl ether) and 1-methoxy-15-methylhexadecane (21, iso-heptadecyl methyl ether), respectively. Peak 22 was subsequently characterized as 1-methoxy-14-methylhexadecane (22, ante-iso-heptadecyl methyl ether). Peak 20 was supposed to be 1-methoxy-methyl-branched hexadecane (20, methyl-branched hexadecyl methyl ether), whose methyl position remained obscure. Stereo chemistry of each optically active carbon in 20 and 22 remained obscure.

Structure elucidation of 1-methoxy-alkenes (unsaturated methyl ethers) in the millipede

Based on calculated C=C double bond increment (∆KI = −20) for Z−9-ene (peak 28) to saturated (peak 30) of standards derived from palm oil, and likewise (∆KI = −25) for Z,Z-9,12-diene (peak 27), peak 16 (∆KI = −21) was characterized as 1-methoxy-Z-9-hexadecene (16, Z-9-hexadecenyl methyl ether), and peak 23 (∆KI = -19) was characterized as 1-methoxy-Z-9-heptadecene (23, Z-9-heptadecenyl methyl ether). Calculated KI for putative C19-OMe was 2143, then peak 31 (KI = 2124) corresponded to the difference of ∆KI = −19 and the structure of peak 31 was elucidated as 1-methoxy-Z-9-nonadecene (31, Z-9-nonadecenyl methyl ether). KI value of peak 19 (1928) indicated −20 to that of peak 21 (1946), then the resulting ∆KI = −20 suggested the structure of peak 19 as 1-methoxy-15-methyl-Z-9-hexadecene (19, Z-9-iso-heptadecenyl methyl ether). Although peak 15 looked like 1-methoxy-hexadecene (15) by GC/MS, its ∆KI = −25 were larger than Z-9-mono-ene (∆KI = −19 ~ −20), and its C=C bond position remained obscure. Peaks 17, 24, and 29 had almost the same mass spectra as peaks 16, 23, and 28 with ∆KI = −14, −13, and −16 corresponding saturated compounds. Those were proposed as being E-isomers, and tentatively elucidated as 1-methoxy-E-9-hexadecene (17, E-9-hexadecenyl methyl ether), 1-methoxy-E-9-heptadecene (24, E-9-heptadecenyl methyl ether), and 1-methoxy-E-9-octadecene (29, E-9-octadecenyl methyl ether). All structures of compounds from O. communis, identified, elucidated, or characterized, are presented in Fig. 4.

Structure elucidation of conventional millipede components

Another five peaks (1, 6, 7, 10, and 26, a total of 50.0%) were conventional polydesmid compounds and identified each as benzaldehyde (1), benzoyl cyanide (6), benzoic acid (7), mandelonitrile (10) and mandelonitrile benzoate (26), using authentic compounds. The other five peaks (2, 3, 4, 5, and 8, in total 4.1%) were also found among Polydesmida and identified as phenol (2), o-cresol (3), p-cresol (4), 2-methoxyphenol (5) and 2-methoxy-5-methylphenol (8), using authentic compounds. Peak 9 (0.5%) was elucidated as 3-methoxy-4-methylphenol (9) by comparison with MS database (Table 1).

Discussion

The present polydesmid millipede has recently revealed the possession of a large amount of waxy compounds (mentioned later) in addition to the conventional chemical defense systems represented by five polydesmid compounds{1, 6, 7, 10, and 26, produced by two enzymes; hydroxynitrile lyase (HNL)11 and mandelonitrile oxidase (MOX)12 from 10 as the common substrate with subsequent chemical and biochemical reactions} and of six phenolic compounds (2, 3, 5, 8, and 9). Then the species corresponds to one of HCN and H2O2 emitter13.

The structures of waxy compounds were elucidated and identified as saturated, unsaturated or methyl branched 1-methoxyalkanes (more than 45.4% of total hexane extracts) by NMR and GC/MS spectra. Most of components (86.6% of total ethers) were identified by co-chromatography with authentic compounds prepared from the palm oil, as follows; 11 (0.7%), 16 (2.2%), 18 (72.5%), 23 (0.7%), 27 (2.6%), 28 (7.0%), and 30 (0.9%). Structures of the other ethers (11.6% of total methyl ethers; 12, 13, 14, 17, 19, 21, 22, 24, 25, 29, and 31) were elucidated by calculation using Kovat’s retention index as summarized in Table 1. The position of a double bond in 15 (1.1%) and that of methyl residue in 20 (0.9%) remained obscure. Alkyl moieties of methyl ethers are mostly identical to those of long chain fatty acids, and presumably have those fatty acids as a precursor. At present, there are no other polydesmid millipedes known to possess those waxy compounds, such as hydrocarbons and fatty acid esters, nor other related presumably functioning as “raincoat compounds”.

As far as our data searches are concerned, no other millipedes including Polydesmida or other animals have been reported to produce 1-methoxyalkanes (methyl alkyl ethers)8,9, except for the spider Nephila clavipes [Arachnida: Araneae]18. The major components of the spider silk extracted by pentane or methylene chloride consist of a complex mixture of methyl-branched 1-methoxyalkanes [total 51 compounds, all of those contained up to four methyl groups in each carbon chain (chain length between C28 and C34)], together with small amounts of hydrocarbons and alcohols18.

As a group of waxy components, fatty acid esters have been distributed in several species of millipedes belonging to Julida, other than methyl- and methoxy-substituted benzoquinones8,9. A mixture of hexadecyl acetate, Δ9-hexadecenyl acetate and Δ9-octadecenyl acetate has been identified in Blaniulus guttulatus [Julida: Blaniulidae]19, likewise hexyl oleate and octyl oleate have been identified in Cibiulus phlepsii and Nopoiulus kochii [Julida: Blaniulidae]20. Hexyl esters of alkanoic acids have also been found in Enantiulus nanus and Julus scandinavius [Julida: Julidae]21. A total of 15 esters, composed of fatty acids (C9–C14, including iso- and ante-iso-) and n-alcohols (C4–C8) have been identified in Anaulaciulus sp. [Julida: Julidae]22. However, distribution of hydrocarbons, as waxy components or body surface compounds, has not been reported in millipedes. Two types of unwettability (raincoat effect) due to chemical compounds have been summarized in Liacaridae (Acari, Oribatida), other than physical and morphological “Lotus effect”; (1) a mixture of C8–C10:2 acid, and their 1,2- and 1-3-di-glycerides, and (2) esters composed of C15 and C16 acids with C14–C17 alcohols23.

In conclusion, 1-methoxyalkanes (a total of 20 compounds of methyl alkyl ethers, a class of compounds) were discovered as components of hexane extracts in the present species. It is only the second example of its presence in the animal kingdom, and it is presumably present on the body surface as a raincoat to keep off water penetration and also to prevent desiccation. The present discovery of unusual 1-methoxyalkanes in this polydesmid millipede might represent evidence of a chemical evolution of the species that adapts and thrives in heavy tropical rainfalls. Further examples of similar species should be expected.

Materials and Methods

Millipedes

The adult species Orthomorpha communis Likhitrakarn, Golovatch & Panha, 2011 [Paradoxosomatidae: Polydesmida], often found individually embedded in soils after heavy rains, were manually collected in Banrai (6°54′38.3″N, 100°28′08.0″E), Hat Yai District, Songkhla Province (Southern Thailand), Thailand in December, 2015, and subsequently reared in the laboratory on leaf litters collected from the site under a natural photoperiod with high humidity (ca. 100% RH) at 20 °C. Sizes of adult were as follows; body length 15.0–27.5 mm, a width of midbody pro- and meta-zona 1.1–2.3 and 1.5–3.1 mm, respectively.

Hexane extraction of millipedes

Five adult millipedes as a group and also one adult millipede (two times) were dipped into n-hexane (1 ml, separately) for three minutes, using appropriate glass vials (5 ml volume). Then, the resultant hexane extracts after separation from residual millipede bodies by decantation were each subjected to gas chromatography coupled with mass spectrometry (GC/MS) analyses.

Analytical methods

GC/MS spectra were obtained as reported24 using Hewlett Packard HP 5975 C Inert XL EI/CI MSD with triple-Axis Detector at 75 eV coupled with a 7890 A GC-system equipped with an HP-5 column (30 m × ϕ 0.25 mm; 0.25 μm in film thickness) operated in the split-less mode at 60 °C for 2 min, then programmed to increase at 10 °C/min to 290 °C, and finally held at this temperature for 5 min. Helium was used as the carrier gas at a flow rate of 1.00 ml/min. GC and GC/MS data were processed using ChemStation (Hewlett Packard Co.), with reference to an MS database (Wiley 9th/NIST 2011 MS Library; Hewlett Packard Co.). In the case of the non-resolved peaks (5 and 6), relative amounts were calculated by selected ion chromatography (SIC) using each base ion (m/z 105 and 109, respectively). Retention indices25 were calculated under the same GC conditions mentioned above, as described in Bodner and Raspotnig26, and were used for structure elucidation. 1H-NMR spectra (400 MHz, TMS at δ00.00 as internal standard) were recorded on a Bruker Biospin AC400M spectrometer.

Chemicals

The following chemicals and solvents were obtained commercially and used as described in the text; two chemicals (1 and 2) from Wako Pure Chemical Industries, Japan, two chemicals (5 and 7) from Nacalai Tesque Inc., Japan, and five chemicals (3, 4, 6, 8, and 10) from Tokyo Chemical Industry Co., Japan. Compound 26 was prepared as reported previously16. Wako Gel C-200, hexane, diethylether (Wako Pure Chemical Industries, Ltd.), lithium aluminum hydride, methyl iodide, and metallic sodium (Junsei Chemical, Japan) were used without purification.

Preparation of standard 1-methoxyalkane mixtures from palm oil

A mixture of alcohols derived from the palm oil by reduction with lithium aluminum hydride were lead to the corresponding mixture of 1-methoxyalkanes using Williamson’s ether synthesis (reaction between sodium alcoholate and methyl iodide). After addition of water to dissolve solids, the reaction products were extracted by hexane. The hexane extracts, without concentration, was poured on a silica gel column (Wako Gel C-200, 300 mg, 0.5ϕ × 2.1 cm in length) prepared without solvent, using a disposable glass pipette (1.5 ml, Iwaki). 1-Methoxyalkanes were obtained as an eluted fraction by 1% ether in hexane.

Separation of millipede components by a silica gel column

To the silica gel column (Wako C-200, 300 mg) similarly prepared as mentioned above, the hexane extracts (1 ml) from seven millipedes was subjected, and the column was successively eluted with hexane (3 ml), 1% Et2O/hexane (3 ml), 2% Et2O/hexane (3 ml), 5% Et2O/hexane (3 ml), 10% Et2O/hexane (3 ml), 50% Et2O/hexane (3 ml), and 100% Et2O (3 ml). All fractions were subjected to GC/MS analysis.

Acknowledgements

This work was supported by JST ERATO Asano Active Enzyme Molecule Project (Grant Number JPMJRER1102), Japan. This research was funded in part by a grant-in-aid for Scientific Research S from The Japan Society for Promotion of Sciences (No. 17H06169) to Y. Asano. The financial support given to A. Nuylert from Ministry of Education, Culture, Sport, Science and Technology (MEXT) of Japan is deeply appreciated.

Author Contributions

A.N. collected millipedes, carried out experiments, participated in the study design and data analysis, and drafted the manuscript. Y.K. carried out GC/MS spectroscopy and drafted the manuscript. T.H. collected and identified millipedes, participated in the study design, and drafted the manuscript. Y.A. participated in data analysis, conceived and coordinated the study, and drafted the manuscript. All authors gave final approval for publication.

Competing Interests

The authors declare no competing interests.

Footnotes

Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

References

  • 1.Aldrich J. Chemical Ecology of the Heteroptera. Annu. Rev. Entomol. 1988;33:211–238. doi: 10.1146/annurev.en.33.010188.001235. [DOI] [Google Scholar]
  • 2.Noge K, Kimura H, Abe M, Becerra JX, Tamogami S. Antibacterial activity of 4-oxo-(E)-2-hexenal from adults and nymphs of the heteropteran, Dolycoris baccarum (Heteroptera: Pentatomidae) Biosci. Biotechnol. Biochem. 2012;76:1975–1978. doi: 10.1271/bbb.120321. [DOI] [PubMed] [Google Scholar]
  • 3.Blomquist GJ, Nelson DR, De Renobales M. Chemistry, biochemistry, and physiology of insect cuticular lipids. Arch. Insect Biochem. Physiol. 1987;6:227–265. doi: 10.1002/arch.940060404. [DOI] [Google Scholar]
  • 4.Raspotnig G. Chemical alarm and defence in the oribatid mite Collohmannia gigantea (Acari: Oribatida) Exp. App. Acarol. 2006;39:177–194. doi: 10.1007/s10493-006-9015-4. [DOI] [PubMed] [Google Scholar]
  • 5.Raspotnig G, Leis H-J. Wearing a raincoat: exocrine secretions contain anti-wetting agents in the oribatid mite, Liacarus subterraneus (Acari: Oribatida) Exp. App. Acarol. 2009;47:179–190. doi: 10.1007/s10493-008-9212-4. [DOI] [PubMed] [Google Scholar]
  • 6.Shimano S, Sakata T, Mizutani Y, Kuwahara Y, Aoki J-I. Geranial: The alarm pheromone in the nymphal stage of the oribatid mite. Nothrus palustris. J. Chem. Ecol. 2002;28:1831–1837. doi: 10.1023/A:1020517319363. [DOI] [PubMed] [Google Scholar]
  • 7.Rodriguez J, et al. Step-wise evolution of complex chemical defenses in millipedes: a phylogenomic approach. Sci. Rep. 2018;8:3209. doi: 10.1038/s41598-018-19996-6. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 8.Makarov, S. E. D.-I. In Minelli, A. (ed) Treatise on Zoology-Anatomy, Taxonomy, Biology. The Myriapoda2 (Brill, 2015).
  • 9.Shear WA. The chemical defenses of millipedes (Diplopoda): biochemistry, physiology and ecology. Biochem. Syst. Ecol. 2015;61:78–117. doi: 10.1016/j.bse.2015.04.033. [DOI] [Google Scholar]
  • 10.Brewer MS, Sierwald P, Bond JE. Millipede Taxonomy after 250 Years: Classification and Taxonomic Practices in a Mega-Diverse yet Understudied Arthropod Group. PLoS One. 2012;7:e37240. doi: 10.1371/journal.pone.0037240. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 11.Dadashipour M, Ishida Y, Yamamoto K, Asano Y. Discovery and molecular and biocatalytic properties of hydroxynitrile lyase from an invasive millipede, Chamberlinius hualienensis. Proc. Natl. Acad. Sci. 2015;112:10605–10610. doi: 10.1073/pnas.1508311112. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 12.Ishida Y, et al. A sacrificial millipede altruistically protects its swarm using a drone blood enzyme, mandelonitrile oxidase. Sci. Rep. 2016;6:26998. doi: 10.1038/srep26998. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 13.Kuwahara Y, Yamaguchi T, Ichiki Y, Tanabe T, Asano Y. Hydrogen peroxide as a new defensive compound in “benzoyl cyanide” producing polydesmid millipedes. Sci Nat. 2017;104:19. doi: 10.1007/s00114-017-1435-y. [DOI] [PubMed] [Google Scholar]
  • 14.Kuwahara Y, Shimizu N, Tanabe T. Release of hydrogen cyanide via a post-secretion Schotten-Baumann reaction in defensive fluids of polydesmoid millipedes. J. Chem. Ecol. 2011;37:232–238. doi: 10.1007/s10886-011-9920-9. [DOI] [PubMed] [Google Scholar]
  • 15.Kuwahara Y, Ômura H, Tanabe T. 2-Nitroethenylbenzenes as natural products in millipede defense secretions. Naturwissenschaften. 2002;89:308–310. doi: 10.1007/s00114-002-0328-9. [DOI] [PubMed] [Google Scholar]
  • 16.Kuwahara Y, Mori N, Sakuma M, Tanabe T. (1Z)-and (1E)-2-Nitroethenylbenzenes, and 2-Nitroethylbenzene as Natural Products in Defense Secretions of a Millipede Thelodesmus armatus Miyosi (Polydesmida: Pyrgodesmidae) Jpn. J. Environ. Entomol. Zool. 2003;14:149–155. [Google Scholar]
  • 17.Golovatch SI, Kime RD. Millipede (Diplopoda) distributions: A review. Soil Organisms. 2009;81:565–597. [Google Scholar]
  • 18.Schulz S. Composition of the silk lipids of the spider Nephila clavipes. Lipids. 2001;36:637–647. doi: 10.1007/s11745-001-0768-7. [DOI] [PubMed] [Google Scholar]
  • 19.Weatherston J, Tyrrell D, Percy J. Long chain alcohol acetates in the defensive secretion of the millipede Blaniulus guttulatus. Chem. Phys. Lipids. 1971;7:98–100. doi: 10.1016/0009-3084(71)90023-5. [DOI] [Google Scholar]
  • 20.Vujisić LV, et al. Chemical defense in millipedes (Myriapoda, Diplopoda): do representatives of the family Blaniulidae belong to the ‘quinone’clade? Chem. Biodiv. 2014;11:483–490. doi: 10.1002/cbdv.201300355. [DOI] [PubMed] [Google Scholar]
  • 21.Huth A. Defensive secretions of millipedes: more than just a product of melting point decrease? Frag. Faun. Warszawa. 2000;43:191–200. [Google Scholar]
  • 22.Shimizu N, Kuwahara Y, Yakumaru R, Tanabe T. n-Hexyl laurate and fourteen related fatty acid esters: new secretory compounds from the julid millipede, Anaulaciulus sp. J. Chem. Ecol. 2012;38:23–28. doi: 10.1007/s10886-012-0063-4. [DOI] [PubMed] [Google Scholar]
  • 23.Brückner A, Stabentheiner E, Leis H-J, Raspotnig G. Chemical basis of unwettability in Liacaridae (Acari, Oribatida): specific variations of a cuticular acid/ester-based system. Exp. App. Acarol. 2015;66:313–335. doi: 10.1007/s10493-015-9914-3. [DOI] [PubMed] [Google Scholar]
  • 24.Kuwahara Y, Ichiki Y, Morita M, Tanabe T, Asano Y. Chemical polymorphism in defense secretions during ontogenetic development of the millipede Niponia nodulosa. J. Chem. Ecol. 2015;41:15–21. doi: 10.1007/s10886-014-0536-8. [DOI] [PubMed] [Google Scholar]
  • 25.Kovats vE. Gas-chromatographische charakterisierung organischer verbindungen. Teil 1: retentionsindices aliphatischer halogenide, alkohole, aldehyde und ketone. Helv. Chim. Acta. 1958;41:1915–1932. doi: 10.1002/hlca.19580410703. [DOI] [Google Scholar]
  • 26.Bodner M, Raspotnig G. Millipedes that smell like bugs:(E)-alkenals in the defensive secretion of the julid diplopod Allajulus dicentrus. J. Chem. Ecol. 2012;38:547–556. doi: 10.1007/s10886-012-0127-5. [DOI] [PubMed] [Google Scholar]

Articles from Scientific Reports are provided here courtesy of Nature Publishing Group

RESOURCES