Chlorophyll analysis by high-performance liquid chromatography

The separation and determination of chlorophylls by high-performance liquid chromatography (HPLC) is described. Chlorophylls and their derivatives were separated by reversed-phase HPLC based on hydrophobic interaction between solute and support, using an octadecyl silica column and elution with 100% methanol. Separated pigments were detected fluorometrically with a sensitivity in the picomole range: the fluorescence response was linear over a wide pigment concentration range. Resolution of five chlorophylls a and four protochlorophyll species esterified with different alcohols was achieved within 22 min in a single experiment. This method can be used for the determination of chlorophyll b, bacteriochlorophyll a esters and products synthesized from chlorophyll, but not for nonesterified pigments, i.e., chlorophyllide, protochlorophyllide and chlorophyll c. The chromatographic mobility of chlorophyll a esterified with different alcohols increases with increasing number of carbon atoms in the esterifying alcohols. The plots obtained from the logarithm of the capacity factor (k′) of these pigments versus the numbers of carbon atoms of the alcohol molecule gave a straight line, thus permitting the estimation of the chain length of unknown pigment esterifying alcohols. This HPLC separation technique did not cause the formation of artifacts. The deviation of the individual retention time for each pigment is less than ±0.5%, thus making this method suitable for the rapid identification and quantification of unknown pigments.     

Changes in chlorophyll and carotenoid contents in radish (Raphanus sativus) cotyledons show different time courses during senescence

Changes of chlorophylls and carotenoids from green to yellow cotyledons of the radish ( Raphanus sativus ) were simultaneously and systematically analysed by high-performance liquid chromatography (HPLC) with photodiode array detection. Twenty-one components, seven chlorophylls and 14 carotenoids, were detectable. Seven chlorophylls and five carotenoids were identified from the results of HPLC analyses. Most chlorophyll species degraded during senescence, whereas carotenoids showed different behaviour in their metabolism depending on pigment species. For instance, during senescence, the contents of lutein and violaxanthin changed only slightly, β-carotene in 5-day-senescent cotyledons became 2.7 times higher than non-senescent leaves. Carotenoids of radish cotyledons were classified into three groups by their changes in concentration during senescence (increased, degraded and constant) and their roles discussed.     

Reversed-phase high-performance liquid chromatography of chlorophylls and carotenoids

Reversed-phase high-performance liquid chromatography with octadecyl- or octylsilylated silica gel as the stationary phase provides a powerful tool in the analysis of chloroplast pigments from higher plants and green algae. Chromatographic columns packed with 10 μm chemically bonded silica gel particles allow the simultaneous separation of chlorophylls a and b, chlorophyll isomers, pheophytins a and b, α-carotene, β-carotene, lutein, violaxanthin, lutein-5,6-epoxide, antheraxanthin, neoxanthin and several minor carotenoids from a single sample within a short analysis time. The quantitative analysis requires a minimum of 1–5 pmol for carotenoids and 5–10 pmol for chlorophylls. Pigment degradation products, formed on polar stationary phases, are not found in reversed-phase high-performance liquid chromatography due to the weak hydrophobic forces on which the separation mechanism is based. The production of altered pigments however, either induced by various treatments or generated during the isolation, can be monitored as the reversed-phase system is selective enough to separate cis-isomers and oxidation products from their parent compounds. The reproducibility of the individual retention time for each pigment is better than ±1.5% which facilitates the identification of unknown pigments. The method is applied to the analysis of the pigment composition of Chlorella fusca, spinach (Spinacia oleracea) chloroplasts, and to the rapid determination of the ratio of chlorophyll a to chlorophyll b.     

SEPARATION OF CHLOROPHYLLS c1c2, AND c3 OF MARINE PHYTOPLANKTON BY REVERSED-PHASE-C18-HIGH-PERFORMANCE LIQUID CHROMATOGRAPHY1

We separated chlorophylls c₁ c₂, and c₃ of marine phytoplankton together with other pigments by a modification of the commonly applied reversed-phase-C18-high-performance liquid chromatography (RP-C18-HPLC) method. However, the chlorophyll c-like pigment 2,4, Mg-divinylpheoporphyrin as monomethyl ester, co-eluted with chlorophyll c₁. The method involves optimization of the mobile phase by using a very high ion strength solvent in combination with a high carbon loaded RP-C18 column. Fingerprints of the various taxonomic groups of algae can thus be developed in a single run, including separation of the carotenoids lutein and zeaxanthin.     

PHOTOSYNTHETIC PIGMENTS IN FIFTY-ONE SPECIES OF MARINE DIATOMS1

The photosynthetic pigments of 51 species (71 isolates) of tropical and sub-tropical diatoms from 13 out of 22 families were examined. These were the Thalassiosiraceae, Melosiraceae, Coscinodiscaceae, Rhizosoleniaceae, Biddulphiaceae, Chaetoceraceae, Lithodesmiaceae, Eupodiscaceae, Cymatosiraceae, Diatomaceae, Naviculaceae, Nitzschiaceae and Phaeodactylinaceae. Pigments were analyzed by cellulose and polyethylene thin-layer chromatography (TLC) and reverse-phase high-performance thin-layer chromatography (HPTLC). All species contained chlorophylls a and c₂ and the carotenoids carotene, fucoxanthin, diatoxanthin and diadinoxanthin. In addition, 14 species (20 isolates) contained one or more of four minor carotenoids, which were not identified further. One species, Thalassiothrix heteromorpha, contained small amounts of a 19′-butanoyloxyfucoxanthin-like pigment, in addition to fucoxanthin. Chlorophyll c₂ was present in all the diatoms tested and occurred together with chlorophyll c₁ in 88% of them. The presence of both chlorophylls c₁ and c₂ therefore can no longer be considered a universal characteristic of the diatom class. Where chlorophyll c₁ was absent or occurred in trace amounts only (8 species, 11 isolates), it was usually replaced by a new chlorophyll c pigment designated chlorophyll c₃, recently characterized from several prymnesiophytes and one chrysophyte. Exceptions were Nitzschia closterium (CS-114), which contained only chlorophyll c₂, and Nitzschia bilobata (CS-47), which contained all three chlorophylls (c₁, c₂ and c₃) in approximately equal amounts. Five species that contained chlorophylls c₁ and c₂ also contained chlorophyll c₃ in trace quantities Quantitative pigment analyses of the 71 isolates showed that chlorophyll concentrations ranged from 0.02 μg. 10⁶ cells^?1 in the smallest diatom, Extubocellulus spinifer, to 174.4 μg. 10⁶ cells^?1 in one of the largest diatoms, Coscinodiscus sp. under the standard growth conditions used. The mean molar ratio of chlorophyll a:c in the 72 isolates was 3.33, with a range of 1.65–7.25. The close similarity between diatom and prymnesiophyte pigmentation was confirmed. Each class has three patterns of pigmentation: viz species with chlorophylls c₁ and c₂ and‘true’fucoxanthin, species with chlorophylls c₃ and c₂ and‘true’fucoxanthin, and species with chlorophylls c₃ and c₂ and fucoxanthin derivatives.     

A PHYTOL-SUBSTITUTED CHLOROPHYLL C FROM EMILIANIA HUXLEYI (PRYMNESIOPHYCEAE)1

A nonpolar chlorophyll c-like pigment was isolated by semi-preparative high performance liquid chromatography from the coccolithophorid Emiliania huxleyi (Lohm.) Hay and Mohler. The visible absorption spectrum of this pigment was similar to that of chlorophyll c₂. However, its nonpolar chromatographic properties were quite different from those of the relatively polar chlorophylls c₂ and c₃ in E. huxleyi and similar to those of chlorophyll a. Analyses by gas chromatography and gas chromatography-mass spectrometry showed that the nonpolar character of this new chlorophyll c was due to the presence of phytol, most likely on the acid side chain of the porphyrin macro-cycle. This is the first example of a phytol-substituted chlorophyll c-like pigment.     

Separation of derivatized glycosphingolipids into individual molecular species by high performance liquid chromatography

The high performance liquid chromatography separation of the perbenzoyl derivatives of the neutral glycosphingolipids (GlcCer, LacCer, GbOse3Cer, GbOse4Cer, and GgOse3Cer) and the p-bromophenacyl and 2,4-dinitrophenyl hydrazide derivatives of the gangliosides (GM4, GM3, GM2, GM1, GD1a) into individual molecular species on a C18 reversed-phase column is described. Peaks were identified by comparing their relative retention times to the relative retention time of the corresponding glycosphingolipid of known molecular species composition. As little as 5 to 10 pmol of each molecular species of neutral glycosphingolipids and 3 to 5 pmol of the gangliosides can be detected. The effects of changes in the proportion of acetonitrile, methanol, and water in the mobile phase and of column temperature on the molecular species separation are described. A procedure for the tentative identification of glycosphingolipid molecular species based on their relative retention times is presented.     

Design, synthesis and properties of synthetic chlorophyll proteins.

A chemoselective method is described for coupling chlorophyll derivatives with an aldehyde group to synthetic peptides or proteins modified with an aminoxyacetyl group at the epsilon-amino group of a lysine residue. Three template-assembled antiparallel four-helix bundles were synthesized for the ligation of one or two chlorophylls. This was achieved by coupling unprotected peptides to cysteine residues of a cyclic decapeptide by thioether formation. The amphiphilic helices were designed to form a hydrophobic pocket for the chlorophyll derivatives. Chlorophyll derivatives Zn-methyl-pheophorbide b and Zn-methyl-pyropheophorbide d were used. The aldehyde group of these chlorophyll derivatives was ligated to the modified lysine group to form an oxime bond. The peptide-chlorophyll conjugates were characterized by electrospray mass spectrometry, analytical HPLC, and UV/visible spectroscopy. Two four-helix bundle chlorophyll conjugates were further characterized by size-exclusion chromatography, circular dichroism, and resonance Raman spectroscopy.     

Light‐induced pigment degradation in leaves and ripening fruits studied in situ with reflectance spectroscopy

Pigment breakdown mediated by activated oxygen species is a consequence and a general symptom of oxidative stress and injury to plants. We have attempted to estimate the patterns of pigment bleaching and follow pigment susceptibility to irradiation as related to the process of senescence/ripening. Light‐induced pigment breakdown was studied in situ in the leaves of a shade‐requiring plant, wax flower ( Hoya carnosa R. Br.), as well as in apple ( Malus domestica Borlh. cv. Zhigulevskoe) and lemon ( Citrus limon Burm. cv. Pavlovsky) fruits, using reflectance spectroscopy. It was found that the sensitivity of plant pigments to photobleaching increases as ripening progresses in lemon fruit. Kinetic analysis showed that in all systems a rapid breakdown of the pigment occurs after a lag‐phase. The signature analysis revealed a common pattern of chlorophyll and carotenoid changes, but degradation of the individual pigments was found to be inhomogeneous. Both in lemon and apple fruits a decrease in reflectance in the band of carotenoid absorption preceded pigment photodestruction. In the fruits, the bulk of chlorophyll b and the long‐wavelength chlorophyll a forms were degraded at early stages of the process whereas the breakdown of both chlorophylls in H. carnosa leaves was more synchronous. Prolonged irradiation induced bleaching of the main chlorophyll a band with maximum at 678 nm in the difference spectra, as well as carotenoids. Some features of reflectance spectra in the bands of chlorophyll and carotenoid absorption were found to be suitable for the differentiation of photo‐induced pigment breakdown from the transformation of the pigments taking place during senescence.     

Changes in pigmentation of phytoplankton species during growth and stationary phase — consequences for reliability of pigment-based methods of biomass determination

In applied water ecology several methods for estimating the biomass or activity of phytoplankton depend on the proportion of accessory pigments (xanthophylls) to chlorophyll a. Therefore, changes in pigmentation during growth and stationary phase were investigated in four different species (Amphidinium klebsii, Euglena gracilis, Prymnesium parvum, Cryptomonas ovata) typical representatives of the major algal groups. The ratios of the different xanthophylls to chlorophyll a depended not only on the growth phase, but also on the species. InAmphidinium andEuglena, the ratio of xanthophylls to chlorophyll rises continuously during the growth phase and declined during the stationary phase. InPrymnesium, quantitative pigmentation was found to be nearly independent of the growth phase. InCryptomonas, however, this ratio was relatively constant during growth, but increased in the stationary phase. In contrast to higher plants, in which the breakdown of chlorophylls occurs before that of the xanthophylls, in three of the species both pigment classes were reduced in parallel when the cultures were in the stationary phase. AgingCryptomonas, however, exhibited a pigment breakdown pattern similar to higher plants. The use of these findings for the widely applied biomass determination by chlorophyll fluorescence and for other pigment-based methods is discussed.     

BIOGENESIS OF CHLOROPLAST MEMBRANES : IV. Lipid and Pigment Changes during Synthesis of Chloroplast Membranes in a Mutant of Chlamydomonas reinhardi y-1

The glycolipid, phospholipid, pigment, and fatty acid content in whole y-1 cells during the greening process have been investigated. The time course of their changes indicates that phosphatidyl glycerol and glycolipids are the main lipids synthesized specifically during illumination of dark-grown cells, concomitant with an increase in the polyunsaturated C18:2 and C18:3 fatty acids. The pigment complex of light-grown cells consists mainly of chlorophylls a and b, lutein, β-carotene, violaxanthin, and neoxanthin. During the greening process, chlorophylls a and b are synthesized in constant proportions (ratio a/b equals 2.6), β-carotene and violaxanthin do not change significantly, and lutein and neoxanthin increase. The molar ratios of the different lipids and pigment to total chlorophyll during greening has been calculated. It was found that during the initial phase of greening when chlorophyll is synthesized at increasing rates, the molar ratios of various lipids and pigments to chlorophyll decrease and tend to become constant when chlorophyll and membrane synthesis proceed at constant rates. The implication of these findings with respect to the concept of membrane assembly through a spontaneous single step process is discussed     

Separation of Chlorophylls c(1) and c(2) from Pigment Extracts of Pavlova gyrans by Reversed-Phase High Performance Liquid Chromatography

Chlorophylls c₁ and c₂ have been separated from total pigment extracts of the alga Pavlova gyrans Butcher using a reversed-phase high-performance liquid chromatography system. Pigments were separated on a 5 micrometer C₁₈ column (25 centimeters × 4.6 millimeters) using a gradient of methanol-acetonitrile-water. Other photosynthetic pigments were also well resolved by the system used. The separation system described may replace current thin layer chromatography methods for qualitative and quantitative determination of chlorophyll c species.     

A new spectrally distinct component in preparations of chlorophyll c from the micro-alga Emiliania huxleyi (Prymnesiophycease)

A new chlorophyll c pigment designated chlorophyll c₃ has been isolated from the coccolithophorid Emiliania huxleyi (Prymnesiophyceae) using reverse-phase high-performance thin-layer chromatography (HPTLC). Its spectral properties were compared with chlorophylls c₁ and c₂ from standard sources. Visible absorption maxima of the new pigment in diethyl ether were at 451, 585 and 625 nm with band ratios of 30.77, 3.79 and 1.00, respectively. Chlorophyll c₂ was present in approximately equal proportions to chlorophyll c₃, with maxima in diethyl ether at 447, 579 and 628 nm and band ratios of 12.26, 1.17 and 1.00, respectively. No chlorophyll c₁ was detected. The visible absorption spectra of the magnesium-free derivatives of both chlorophylls c₂ and c₃ from E. huxleyi in acetone were also recorded. The new chlorophyll c₃ pigment was chromatographically and spectrally distinct from a similar pigment, magnesium 2,4-divinylpheoporphyrin a₅ monomethyl ester, present in prasinophyte algae, with which it could have been confused.     

Pigment analysis of chloroplast pigment-protein complexes in wheat

Pigment-protein complexes separated from wheat (Triticum aestivum L. selection ND96-25 by two gel electrophoresis techniques were analyzed by high-performance liquid chromatography for chlorophylls and carotenoids. The two techniques are compared, and pigment analyses are given for the major reaction centers and light-harvesting complexes. Reaction centers contain mostly chlorophyll a, carotene, and lutein, whereas light-harvesting complexes contain chlorophyll a, chlorophyll b, lutein, and neoxanthin. The amounts of violaxanthin are variable.     

OCCURRENCE OF PHYIWATED CHLOROPHYLL c IN ISOCHRYSIS GALBANA AND ISOCHRYSIS SP. (CLONE T-ISO) (PRYMNESIOPHYCEAE)1

The pigment composition of two clones of Isochrysis galbana Parke (CCMP 1323 and CCAP 927/1), and Isochrysis sp. (clone T-ISO) was analyzed by high-performance liquid chromatography using a polymeric octadecylsilica column. Fluorescent peaks with retention times higher than chlorophyll a were detected for all three clones. The corresponding pigments were isolated and characterized in terms of their visible absorbance and fluorescence spectra. The pigments were similar to phytol-substituted chlorophyll c, previously isolated from Emiliania huxleyi (Lohm.) Hay and Mohler and other species containing chlmophyll c₃. The presence of phytol-substituted chlorophyll c in I. galbana which lacked chlorophyll c₃, increases the diversity of chlorophyll patterns for the Haptophyta, which can be grouped, at present, into six different pigment types. This is the jrst observation of a haptophyte containing the apolar phytylated chlorophyll c-like pigment but lacking chlorophyll c₃.     

A multichannel atomic absorption instrument: simultaneous analysis of zinc, copper, and cadmium in biologic materials

A new method is deseribed for the extraction and determination of chlorophylls a and b. The method is suitable for use with both normal and regreening nitrogen-deficient Chlorella fusca. The assay involves extraction of chlorophylls by an alkaline pyridine reagent which converts the isocyclic ring of the pigment to a cyclic hydroxylactone. Millimolar extinetion coefficients for the hydroxylactone derivatives of both chlorophylls a and b have been determined at 419 and 454 nm. Using these coefficients, equations have been derived for the calculation of chlorophyll a and b concentrations. The new chlorophyll assay has been compared with other assays which involve the extraction of the pigments with 80% acetone or methanol. The new procedure extracts chlorophylls from rormally grown C. fusca more readily than methanol; the chlorophylls of normal Chlorella cannot be extracted with 80% acetone. The new assay is especially useful in the study of chlorophyll synthesis in regreening nitrogen-deficient C. fusca since the chlorophylls present in these deficient cells cannot be completely extracted with acetone, methanol, methanol-dimethylsulphoxide mixtures, or KOH-methanol.     

ULTRASTRUCTURE AND PIGMENTS OF TWO STRAINS OF THE PICOPLANKTONIC ALGA PELAGOCOCCUS SUBVIRIDIS (CHRYSOPHYCEAE)1

The organelle ultrastructure and photosynthetic pigments of a new isolate of the picoplanktonic alga Pelagococcus subviridis Norris from the East Australian Current was compared with the North Pacific Ocean type species. No differences in the ultrastructure of the two isolates were observed. Mitosis was studied in detail in the Australian strain, and showed two unusual features: the de novo appearance of centrioles prior to mitosis, and the formation of a small, extra-nuclear spindle. The major carotenoids in both strains were fucoxanthin and a 19′-butanoyloxyfucoxanthin-like pigment, with diadinoxanthin and diatoxanthin as secondary pigments. Several minor carotenoids have not yet been identified. In addition to chlorophylls a and c₂, a new chlorophyll c derivative (chlorophyll c₃), present in both strains, was separated by high-performance thin-layer chromatography (HPTLC). The Australian isolate, unlike the type material, showed no evidence of chlorophyllase activity during cell harvest and extraction. While the pigment composition suggests affinities with certain newly examined prymnesiophytes, organelle ultrastructure indicates Pelagococcus to be a member of the Chrysophyceae. Mitosis is, however, atypical of both Prymnesiophyceae and Chrysophyceae, and if this picoplanktonic alga is to be retained in the Chrysophyceae it must be seen as a most unusual member.     

Chlorophylls attached to lipid and protein globules, absorption and fluorescence spectra, photo-oxidation.

The precipitation of chlorophylls upon lipid and protein globules suspended in an aqueous buffer yields a partial model of photosynthetic membranes. The absorption and fluorescence spectra of the model are investigated as well as the photo-oxidation of the chlorophylls (bleaching) by dissolved oxygen. It is shown that pigment--pigment interactions occur in such systems, by (a) the appearance of absorption bands characteristic of crystalline or highly ordered chlorophyll at high pigment concentrations, (b) the chlorophyll a-type of fluorescence of systems containing chlorophyll a and chlorophyll b where the latter is selectively excited, and (c) the kinetics of photo-oxidation which suggest that chlorophylls can only be bleached when they are dimerized.     

Are Bryophytes Shade Plants? Photosynthetic Light Responses and Proportions of Chlorophyll a,Chlorophyll b and Total Carotenoids

BACKGROUND AND AIMS: Data are presented from 39 species of mosses and 16 liverworts for ratios of chlorophylls and total carotenoids, and light saturation of photosynthetic electron flow or photosynthetic CO2 uptake, in relation to the postulate that bryophyte cells in general show shade-plant characteristics. METHODS: Pigment concentrations were measured by spectrophotometer in 80 % acetone extracts. Light-saturation curves were constructed by (modulated) chlorophyll florescence and for some species by infra-red gas analysis. KEY RESULTS: The pigment measurements were widely variable but broadly in line with the findings of previous authors. Median values (mosses/liverworts) were: total chlorophyll, 1.64/3.76 mg g(-1); chlorophyll a : b, 2.29/1.99; chlorophylls : carotenoids, 4.74/6.75). The PPFD values at 95 % saturation (estimated from fitted curves) also ranged widely, but were almost all <1000 micromol m(-2) s(-1); the median for mosses was 583 and for liverworts 214 micromol m(-2) s(-1). The two highest PPFD95% values were from Polytrichum species with lamella systems forming a ventilated photosynthetic tissue. Total chlorophyll, chlorophyll a : b and chlorophylls : carotenoids all correlated significantly with PPFD95%. CONCLUSIONS: Bryophytes include but are not inherently shade plants. Light-saturation levels for species of open sun-exposed habitats are lower than for vascular sun plants and are probably limited by CO2 diffusion into unistratose leaves; this limit can only be exceeded by bryophytes with ventilated photosynthetic tissues which provide increased area for CO2 uptake.