Approach

Our decision to employ MALDI mass spectrometry, in this and all our prior analysis was impelled by:

1. 1. Unknown phase mixtures can be handled.

2. 2. A useful degree of laser fragmentation contributes to the structural analysis.

3. 3. There are two stand-out matrix molecules, CHCA and SA, that have reliable, yet very different protonation rates (Lu et al., Reference Lu, Chu, Lin, Wu, Dyakov and Chen2015). When their results coincide, uncertainty is removed.

4. 4. Even when collections of small crystals are studied, as in this work, it is not necessary to grind the crystals as partial solvation is achieved in MALDI matrix solutions after 1 h at room temperature.

We came into the measurements knowing that the Orgueil crystals likely contained hemoglycin because they derive from the interphase of the relevant Folch extractions, where hemoglycin was the dominant chemical (McGeoch et al., Reference McGeoch, Dikler and McGeoch2021). To anticipate the results, we have obtained mass spectrometry confirmation in both Orgueil and fossil stromatolite that the 1494 Da hemoglcyin core unit (McGeoch et al., Reference McGeoch, Dikler and McGeoch2021) comprises essentially 100% of the crystalline material that is able to be solubilized.

Basic observations from mass spectrometry

A very consistent mass spectrometry (MS) pattern was seen in all samples, indicating that the crystal preparation process had universally selected the same molecule, whether from Orgueil or Stromatolite. In every sample the MALDI spectrum contained only two main peaks, one at 1494 m/z, corresponding to the hemoglycin ‘core unit’ (McGeoch et al., Reference McGeoch, Dikler and McGeoch2021) and the second at 760 m/z, which was typically five times higher in summed ion count and was the exclusive fragment of 1494 m/z observed in the present work. The 760 m/z fragment comprises a single polyglycine strand from the antiparallel pair that comprise the central body of hemoglycin. It does not show ⁵⁴Fe side peaks (McGeoch et al., Reference McGeoch, Dikler and McGeoch2021) beside the ‘monoisotopic’ peak, and hence the fragment does not carry iron.

Figure 4 shows for Orgueil crystal sample (O1_2, run 1, SA) the 760 m/z peak system on the left, and the 1494 m/z system on the right. They were each fitted to a global ²H enhancement, giving via 760 m/z analysis δ ²H = 54 000 ± 3000 per mil, and via the 1494 m/z analysis δ ²H = 51 000 ± 3000 per mil. Definitions of ‘global’ and ‘per mil’ are given in Section 1.3.

Figure 4.

Data from sample O1_2, with sinapinic acid matrix. On the left is the 760 m/z fragment that is the sole product from the break-up of the 1494 molecules. On the right, the 1494 m/z peak system.

In summary, the strong polymer rod interconnections of hemoglycin rendered MS analysis for the 1494 m/z subunit itself fairly difficult. This was an inevitable side-effect of having a strong space polymer. The difficulty persisted in spite of mixing in MALDI solvent for 1hour (‘run 1’), or 72hrs (‘run 2’, with improved signal-to-noise relative to ‘run 1’). Earlier it had been established that 1 h in the matrix with 50% acetonitrile and 0.1%TFA was necessary to get the polymer solvated. Immediate MALDI approximately 15 min after applying to the MALDI plate, yielded no peaks at all with the polymer not leaving the crystals for the matrix.

Isotope analysis

The enrichment of ²H relative to H is defined by the ‘per mil’ δ (⁰/₀₀) measure:

$$\delta^2H( {^0 /_{00}} ) = \left({\displaystyle{{{( {^2 H/H} ) }_{SAMPLE}} \over {{( {^2 H/H} ) }_{VIENNA}}}-1} \right)\times 1000\ {\rm in\ which\ }( ^2H/H) _{VIENNA}$$

= 155.76 ± 0.05 × 10⁻⁶ (IAEA, Vienna, 1995).

Without separate knowledge of ¹⁵N enhancement in hemoglycin we fitted the prominent isotope enrichments as if ²H was the only contributor. When ¹⁵N values come available the quoted ‘global’ ²H enrichments may be modified as follows where Δ represents the degree of change:

Δ(δ ²H) = −7.73Δ(δ ¹⁵N). This relationship holds for polymers of glycine and hydroxyglycine that have N_H/N_N = 3 and may be scaled via the relationship R_NN_N/R_HN_H = 7.73 (⁰/₀₀) using the R_N and R_H values listed below. The following isotope ratios (IAEA, Vienna, 1995) are taken as terrestrial standards:

In previous work (McGeoch et al., Reference McGeoch, Dikler and McGeoch2021, Reference McGeoch, Samoril, Zapotok and McGeoch2023b) we concluded that ¹³C and ¹⁸O variations from terrestrial are far less than ¹⁵N and ²H variations in polymer amide from carbonaceous chondrites.

The first identification of hemoglycin in meteorites via MALDI (McGeoch et al., Reference McGeoch, Dikler and McGeoch2021) showed that it carried heavy isotopes ratios such as ²H/H, ¹³C/¹²C, ¹⁵N/¹⁴N, etc. at levels far above terrestrial standards, at least in the cases of ²H and ¹⁵N. An isotope fitting routine was written (McGeoch et al., Reference McGeoch, Dikler and McGeoch2021) with no internal approximations, in which trial values of the isotope ratios are input and the output is compared to experimental MALDI peak strengths. Figure 5, curve A, shows a stromatolite hemoglycin molecular peak complex at m/z 1494 (sample S2_1 (CHCA)). The highest isotopologue occurs at the n = +1 location relative to the n = (0) ‘monoisotopic’ peak. Curve B in Fig. 5 is the calculated complex for a ‘global’ (i.e. equivalent ²H) enhancement of 52 000 per mil, but it is expected that in practice there would be a significant ¹⁵N component, as seen in Acfer 086 (McGeoch et al., Reference McGeoch, Samoril, Zapotok and McGeoch2023b). This would reduce the actual ²H/H ratio by the amount discussed above. ‘Global ²H’ fitting to the higher signal-to-noise ratio run 2 data set, from both the 1494 and 760 components, is summarized in Table 2. In contrast, a simulation with wholly terrestrial isotope levels gives the very different curve (Fig. 5C), in which the highest peak is the (0) isotopologue.

Figure 5.

Vertical axis is intensity (arbitrary units) and horizontal axis m/z. A: sample S2_1 peak complex at 1494 m/z. B: variation of ²H to fit the isotopologue intensities in curve A (the fit required δ ²H = 52 000 per mil). C: the same molecule simulated at terrestrial (Vienna) isotope values.

Table 2.

Isotope analysis for run 2 data set

Enhancements in parts per mil.

‘xx’ represents saturated signal or too low signal relative to noise.

Additional first order diffraction data from crystals and ooids

In Section S3 additional diffraction data is given on (a) crystals in fossil stromatolite extract and (b) ooids from both present day and fossil stromatolite. Out of the fossil samples, only fossil No. 2 from Wyoming (provenance in Methods) yielded any ooids. X-ray diffraction results for ooids in the two present day stromatolites and in a second Wyoming sample, No. 2, are compared in Table S3.1. No ooids could be found in Fossil stromatolite No. 1.

In regard to (a): In Table S3.1 there was a degree of commonality between different crystal samples of Wyoming Fossil No. 1, and a match between fossil stromatolite and the prior report of diffraction from a fiber crystal of meteorite Acfer 086. The agreement related to the proposed separation of iron atoms at the junction of hemoglycin rods in a rectangular lattice (McGeoch and McGeoch, Reference McGeoch and McGeoch2021).

In regard to (b): Table S3.2 compares ring patterns in ooids (provenance in Section S3.2). The Shark Bay ooids are 1. as found, and 2. acid treated as in Methods. The San Salvador ooids were the most recent. Many of the rings were identified as aragonite. Interestingly the 2.1 Gya fossil also contained aragonite, implying a ‘mild’ thermal history in view of the tendency for aragonite to transition into more stable calcite at high temperatures (Parker et al., Reference Parker, Thompson, Lennie, Potter and Tang2010).

Amide I components as an indicator of secondary structure

Hemoglycin, primarily composed of antiparallel strands of glycine, has the same peptide backbone as the synthetic polypeptide poly-L-lysine which has been extensively studied. Susi et al. (Reference Susi, Timasheff and Stevens1967) reported infrared absorption measurements of the transition from random conformation through alpha-helix to antiparallel-chain pleated beta sheet. For poly-L-lysine in the random configuration there was a single amide I band centred at 1647 cm⁻¹ (6.07 μm) that was relatively broad at 40 cm⁻¹. After transition to an antiparallel beta sheet the amide I band was split into two components, the a− at 1616 cm⁻¹ (6.19 μm) and the a+ at 1690 cm⁻¹ (5.92 μm) in the case of H₂O solution, each having a relatively narrow width of <20 cm⁻¹. In that work the related amide II band, typically seen at about 1550 cm⁻¹ (6.45 μm), was suppressed by deuteration of the amide nitrogen (Blout et al., Reference Blout, De Loze and Asadourian1961; Susi et al., Reference Susi, Timasheff and Stevens1967) a consequence of D₂O being preferentially used (Susi et al., Reference Susi, Timasheff and Stevens1967) in order to avoid H₂O absorption around 6 microns.

The degree of amide I splitting increases with the areal extent of the antiparallel beta sheet, details reported by Cheatum et al. (Reference Cheatum, Tokmakoff and Knoester2004). In (Cheatum et al., Reference Cheatum, Tokmakoff and Knoester2004, Fig. 4) it is found that the splitting is mostly accomplished at the scale of 4 × 4 unit cells in a model, where each unit cell covers four amino acid residues, two in one chain hydrogen-bonded to a pair in an adjacent antiparallel chain. The lower frequency peak a−, at 1635 cm⁻¹ (6.12 μm) in Cheatum et al. (Reference Cheatum, Tokmakoff and Knoester2004), is always much more intense than the up-shifted a+ peak at 1680 cm⁻¹ (5.95 μm). This splitting does not occur at all in a two-strand antiparallel beta sheet, but always occurs in extended antiparallel beta sheets to the extent that numerous authors have identified the amide I splitting as a reliable marker for the antiparallel beta sheet secondary structure (Miyazawa, Reference Miyazawa1960; Miyazawa and Blout, Reference Miyazawa and Blout1961; Chirgadze and Nevskaya, Reference Chirgadze and Nevskaya1976; Cheatum et al., Reference Cheatum, Tokmakoff and Knoester2004). The calculated strength ratio (Chirgadze and Nevskaya, Reference Chirgadze and Nevskaya1976) of a+ to a- is low, as seen experimentally in poly-L-lysine (Demirdoven et al., Reference Demirdoven, Cheatum, Chung, Khalil, Knoester and Tokmakoff2004) and again in the present data for hemoglycin.

Analysis of the infrared absorption

1. 1. The amide bands (inset to Fig. 8) dominate the mid-IR absorption in both meteorite and ooid samples.

2. 2. Both samples show Amide I splitting into two components: a strong lower frequency component and a very much weaker higher frequency component. These are identified with the extensively researched a− and a+ components, respectively. The degree of splitting depends upon the extent of the sheet and whether it has multiple layers. The SM2 crystal has less extensive sheets, correlated with less splitting. In support of this is the presence in SM2, but not in ooid, of a very strong 3300 cm⁻¹ (3.03 μm) band due to N-H stretch, implying a large component of N-H groups that are freely vibrating as opposed to being involved in the C = O--H-N hydrogen bond within an extended sheet (Fig. S1.2 for illustration of N-H stretch and antiparallel beta sheet).

Figure 8.

Reproduced from (McGeoch and McGeoch, Reference McGeoch and McGeoch2024, Fig. 3) Mid-infrared absorption spectra of Meteorite crystal SM2 (black lines) and Shark Bay stromatolite ooid (red lines). Inset: Amide I components filled triangles. Amide II components circles.

In view of the above we conclude that each of the substances under test is a polymer of amino acids arranged in an extended antiparallel beta sheet.

1. 3. The amide II band is also seen in both samples, at 1534 cm⁻¹ (6.52 μm, ooid) and 1550 cm⁻¹ (6.45 μm, SM2 crystal). The Amide II band of hemoglycin in ooid is more intense than amide I, contrary to the observation in SM2 and to the approximately 0.5 ratio expected for amide II/amide I in an extended antiparallel beta sheet (Chirgadze and Nevskaya, Reference Chirgadze and Nevskaya1976; Moore and Krimm, Reference Moore and Krimm1976). The reason for this anomalous Amide II intensity in ooid is not known.

In the ooid data of Fig. 8 the complex of bands between 6.8 and 7.1 μm (inset) is due to amorphous calcium carbonate (Avaro et al., Reference Avaro, Ruiz-Agudo, Landwehr, Hauser and Gebauer2019), additionally identified by its diminution with longer acid treatment. In the same region the meteoritic spectrum has strong and relatively sharp absorptions at 1462 cm⁻¹ (6.84 μm) and 1377 cm⁻¹ (7.26 μm) that are not spatially correlated with the amide band absorptions within the crystal. They are from a non-amide source that has been identified (Tielens et al., Reference Tielens, Allamandola, Bregman, Goebel, D'Hendecourt and Witteborn1984) as most probably saturated hydrocarbons, the closest match being to pentane, which has CH₂ deformation bands at 1470 cm⁻¹ (6.80 μm) and 1378 cm⁻¹ (7.26 μm). Saturated hydrocarbons may constitute more than 30% of all the carbon in the line of sight to these protostar sources (Tielens et al., Reference Tielens, Allamandola, Bregman, Goebel, D'Hendecourt and Witteborn1984). We emphasize that hemoglycin in material ultimately derived from a molecular cloud has hydrocarbon bands that are known to be dominant in the interstellar medium (McGeoch and McGeoch, Reference McGeoch and McGeoch2024) whereas the recent ooid FTIR had no hint of these saturated hydrocarbons.