Open Access
Issue
OCL
Volume 23, Number 2, March-April 2016
Article Number A202
Number of page(s) 8
Section Innovation
DOI https://doi.org/10.1051/ocl/2015052
Published online 22 October 2015

© T. Dulermo et al., published by EDP Sciences, 2015

Licence Creative CommonsThis is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1 Introduction

Lipid-based chemicals and biofuels are of great interest in the current context of petroleum resource rarefaction. At present, the lipids used for green chemistry and energy are mostly triacylglycerols (TAG) extracted from crop seeds or animal fats (Octave and Thomas, 2009). Because of the competition with food usage, the use of these lipid sources is questionable. Scientists and industries are working collaboratively to identify and develop alternative renewable sources of lipids for non-food use. In the past decade, oleaginous single-cell microorganisms have reached the forefront of this research because of their high efficiency for TAG production or storage (Garay et al., 2014; Liu et al. 2013). For most, their lipid metabolic and biochemical pathways have been identified and their growth on refined simple carbon sources is well-described (Blazeck et al., 2014; Comba et al., 2013). However, their optimal valorization in cost-effective processes necessitates the optimization of their growth on less expensive substrates, such as wastes or lignocellulosic residues.

Lignocellulose constitutes the main part of plant biomass and is available either as a byproduct of the agriculture and food industries (brans and stems) or as dedicated biomass feedstocks (wood and fiber crops). Thus, it represents an important, renewable carbon pool for the production of bioenergy (Somerville et al., 2010) and biomolecules of interest, in particular by bacterial bioconversion (Mathews et al., 2015). Efficient exploitation remains challenging because this biomass is complex (Menon and Rao, 2012). Indeed, the lignocellulose of the secondary, lignified plant cell wall is composed of an interpenetrated assembly of three polymers: cellulose, hemicelluloses, and lignin. While cellulose and hemicelluloses are easily converted into sugars by enzymes, the presence of lignin, a hydrophobic phenolic polymer, is responsible for lignocellulose’s overall recalcitrance to the enzymatic deconstruction processes (Zhao et al., 2012).

The objective of this study was to assess the possibility of converting lignocellulose into lipids of interest for industrial use with microorganisms known for their wood-degrading activity and constituent lignin-degrading enzymes. For this study, oilseed crop lignocellulosic residues, i.e., sunflower stalks and rapeseed straw, were chosen, as they are abundant, oleaginous coproducts in Europe and seem to be promising sources of biomass for biofuel and paper production (Mazhari Mousavi et al., 2013; Ziebell et al., 2013). Because data regarding their chemical compositions are rare, structural analyses useful for their optimal valorization in biorefinery processes were carried out. To assess the potential of these materials to be used as substrates for lipid production, Streptomyces, a Gram-positive filamentous soil bacteria, was used for growth and bioconversion tests. Bacteria of this genus are well-known for their natural ability to degrade lignocellulose because their genomes possess enzymatic pathways involved in the degradation and catabolism of lignin residues (Davis and Sello 2010; Davis et al., 2012). Indeed, bacteria belonging to the actinomycetes group are of great interest in the context of bioconversion of lignocellulose into high-value bioproducts. Some species, such as Rhodococcus and Streptomyces, are described as oleaginous and can accumulate more than 20% of their dry weight as TAG (Alvarez and Steinbuchel 2002; Deniset-Besseau et al., 2014; Olukoshi and Packter 1994). Rhodococcus was shown to be able to accumulate up to 87% of its dry weight as TAG when grown using olive oil as the substrate (Alvarez et al., 1996). Recently, Rhodococcus was engineered to produce TAG using lignocellulosic residues as substrates. R. opacus DSM 1069 and PD630 are able to convert lignin into TAG (Kosa and Ragauskas, 2012). Efforts have also been devoted to constructing strains capable of utilizing xylose, an abundant sugar in lignocellulosic residues. A xylose-fermenting Rhodococcus strain was constructed using heterologous expression of the Streptomyces enzymes involved in the xylose metabolism pathway (Kurosawa et al., 2013; Xiong et al., 2012). Interestingly, the Streptomyces species has the natural capacity to grow on and catabolize the phenolic compounds and polysaccharides present in lignocellulose (Antai and Crawford 1981; Crawford 1978; Davis and Sello 2010; Vetrovsky et al., 2014). In addition, Streptomyces species, historically studied and exploited for antibiotic production, can also accumulate TAG under specific nutritional conditions (high C/N ratios) (Arabolaza et al., 2008; Comba et al., 2013; Le Marechal et al., 2013).

In this study, the capacity of Streptomyces lividans TK 24 to grow on agricultural lignocellulosic residues from Brassica napus and Helianthus annuus, some of the main oleaginous crops in Europe, was investigated. The polysaccharide, lignin, and fatty acid contents of these unconventional fermentation substrates were first assessed. Then, bacterial cultures in the presence of these substrates were performed and their growth was determined using bacterial fatty acid content as a biomarker. The production of bacterial fatty acids using these substrates was demonstrated, revealing that these lignocellulosic residues could be valorized in bioconversion processes with these microorganisms.

2 Material and methods

2.1 Lignocellulosic feedstocks

Brassica napus (Rapeseed, Rap1 and Rap2 samples) and Helianthus annuus (Sunflower, Sun1 and Sun2 samples) agricultural samples (straws or stalks) were provided by the Organisation Nationale Interprofessionnelle des Graines et Fruits Oléagineux (Onidol, France). They were ground with a hammer mill to pass through a 1-mm screen. Pictures of the lignocellulosic samples were obtained using an illuminated binocular magnifier (Nikon SMZ800) and a Nikon Coolpix 4500 digital camera.

2.2 Strains, media, and culture conditions

The strain used throughout this study was Streptomyces lividans TK24. Lignocellulosic substrates (1.2 g) were sterilized with 19 ml of water in 150-ml growth flasks, and 1 ml of minimal medium without glucose. (Coze et al., 2013) was added to obtain a final volume of 20 ml. Inoculations were done with 3 × 108 spores per flask. Positive growth controls (without lignocellulosic substrates) were made using 2% (v/v) glucose, arabinose, or xylose as the carbon sources. Cultures were performed for 6 days at 30 °C while shaking at 200 rpm.

2.3 Lignocellulose fractionation

Lignocellulosic feedstocks (5 g) were sequentially extracted using an accelerated solvent extraction device (ASE 350, Dionex, USA). Extraction was performed following a two-step procedure (Fig. 1); the first step was with water (total volume, 200 ml), and the second step was with ethanol (total volume, 110 ml). Each step was performed using three 7-min extraction cycles at 100 °C and 110 bar under a nitrogen atmosphere. In parallel, the feedstocks were submitted to a single-step water extraction. The remaining residues were dried in an oven at 50 °C for 48 h (until constant mass was achieved), and the water and ethanol supernatants were stored at −20°C.

thumbnail Fig. 1

Scheme of two-step accelerated solvent extraction (ASE) procedure for the recovery of water and water-ethanol total extractives.

Extractions were performed in duplicate for each initial sample. The water extractives and total extractives contents were calculated from the weight mass loss and expressed with respect to the total initial dry weight using the following equations: %waterextractives=initialmassmassofwaterextractionresidueinitialmass×100%totalextractives=initialmassmassoftwostepextractionresidueinitialmass×100\begin{eqnarray} \label{eq1} &&\% \ water\ extractives \notag\\ &&= \frac{initial\ mass-mass\ of\ water\ extraction\ residue}{initial\ mass}\times 100 \\ \label{eq2} &&\% \ total\ extractives \notag \\ &&=\frac{initial\ mass-mass\ of\ two\ step\ extraction\ residue}{initial\ mass}\times 100 \end{eqnarray}For each sample, the results were calculated as the mean values and standard deviation of the averages obtained for both duplicates.

2.4 Lignocellulose characterization

All of the following analyses were performed in duplicate on the residues of two distinct extractions from each initial sample. For each sample, the results were calculated as the mean values and standard deviation of the averages obtained for both duplicates.

2.4.1 Lignin quantification

The lignin content of the two-step extraction residues was determined using the standard Klason method (Dence and Lin, 1992). The samples (300 mg) were suspended in 3 ml of sulfuric acid solution (72% p/v) for 2 h at 20 °C before being diluted to a 5% p/v final sulfuric acid concentration and heated under reflux for 4 h. The reaction mixture was filtered on a glass microfiber filter, and the remaining material was dried in an oven at 100 °C for 12 h. The lignin content was calculated from the mass of the final solid material after correction for its ash content.

2.4.2 Lignin structural analysis

Lignin structure evaluation was performed on the two-step extraction residues (5 to 10 mg) using the thioacidolysis procedure (Lapierre et al., 1995). The determination of the main p-hydroxyphenyl (H), guaiacyl (G), and syringyl (S) lignin-derived monomers involved in β-O-4 bonds, analyzed as their trimethylsilylated (TMS) derivatives, was carried out using specific ion chromatograms reconstructed at m/z239 for H monomers, 269 for G monomers, and 299 for S monomers.

2.4.3 Sugar quantification

The neutral sugar contents were determined by high-performance ion exchange chromatography (column: 4 × 250mm, Carbopac PA1, Dionex, USA; eluent: 4 mM sodium hydroxide, 1 ml/min) using a pulsed amperometric detector. The initial feedstock, water extraction residues, and two-step extraction residues were submitted to acidic hydrolysis prior to sugar analysis. The samples (10 mg) were suspended in 125 µl of a 72% (p/v) sulfuric acid solution for 1 h at ambient temperature and then 100 °C for 2 h before filtration of the reaction mixture as described above. The sugar content was calculated using fucose as an internal standard.

2.5 Determination of fatty acid content in feedstocks before and after Streptomyces growth

Samples were freeze-dried for 72 h and then heated for 90 min at 80 °C in the presence of 16 ml of 2.5% (v/v) sulfuric acid in methanol. Dodecanoic acid (Sigma-Aldrich) was added (400 µg for each sample) as the internal standard for quantification. Fatty acid methyl esters (FAME) were extracted via the addition of 24 ml of 150 mM NaCl, 2.5 ml of hexane, vigorous shaking, and centrifugation at 1000 g for 15 min. The organic upper phase of the samples was separated by gas chromatography using a 7890A chromatograph (Agilent, USA) with a Factor Four VF-23 ms 30-m × 0.25-mm capillary column (Agilent, USA). The carrier gas was helium at an inlet flow rate of 1 ml/min. The column temperature began at 40 °C for 1 min, ramped to 130 °C at 40 °C/min, remained at 130 °C for 1 min, ramped to 160 °C at 1 °C/min, remained at 160 °C for 1 min, ramped to 210 °C at 40 °C/min, and finally remained at 210 °C for 4 min. Identification of FAME peaks was based on retention times obtained for standards (FAME mix from Sigma-Aldrich and GLC-110 mix from Biovalley). The quantification was made via flame ionization detection at 270 °C. The total amount of fatty acids was calculated from the ratio between the sum of the FAME peak areas and the dodecanoic acid methyl ester peak area.

2.6 Microscopy observations

Streptomyces cultures on lignocellulosic residues were monitored using a Zeiss Axio Imager microscope (Germany) with Nomarski optics and a Roper CoolSnap HQ2 camera (USA) coupled to a Zeiss AxioVision driver.

Table 1

Composition (% dry basis; mean (standard deviation)) and lignin characteristics of rapeseed straw (Brassica napus) and sunflower stalks (Helianthus annuus).

thumbnail Fig. 2

Macroscopic observation of oleaginous lignocellulosic residues. Rapeseed straw (A, B) and sunflower stalk (C, D) agricultural residues were observed before (A, C) and after (B, D) grinding with a hammer mill to obtain residues with sizes compatible with biochemical analysis and Streptomyces growth tests.

3 Results and discussion

3.1 Biomass pretreatments

Rapeseed straw and sunflower stalks (two batches for each species) were obtained from the agricultural stocks. The size of the crop product pieces ranged from a few millimeters to several tens of centimeters (Figs. 2A and 2C). To reduce heterogeneity and obtain substrates compatible with chemical analysis and Streptomyces growth tests, pretreatments of the biomaterials were performed. First, the samples were crushed to homogenize them and reduce the size of their fragments (up to 1 mm, as shown in Figs. 2B and 2D) to optimize component extraction and increase surface contact with the Streptomyces mycelium. Second, sequential extractions with water and ethanol were performed. The objective of the extraction was to recover extractive-free residues as required for the analysis of the cell wall components (lignin and polysaccharides) and to assess the influence of soluble compounds on Streptomyces growth.

3.2 Composition of the lignocellulosic feedstocks and residues

3.2.1 Extractives

Rapeseed straw and sunflower stalk contained 19.3% and 26.1% water extractives, respectively, on average. A subsequent extraction with ethanol removed 1.5% and 1% of the soluble compounds from these feedstocks, respectively (Tab. 1).

3.2.2 Lignin content and structure

The lignin contents of rapeseed straw and sunflower stalk were 17.4% and 15.6%, respectively, based on the average of two batches (Tab. 1). These values are in the range of lignin contents found for other agro-resource stems (13% to 22% according to Mood et al., 2013) but lower than that of wood (Dence and Lin, 1992). They are in agreement with other data available for sunflower (13.4% according to Mood et al. 2013, 19.9% according to Caparrós et al. 2008, and 18.3% according to Mazhari Mousavi et al., 2013) and rapeseed stalk (16.0% according to Mazhari Mousavi et al., 2013). However, Kang et al. (2012) reported a lower lignin content, 6.9%, for rapeseed stem. These variations can be explained by differences in the developmental stages of the harvested material, as previously observed for maize (Boon et al., 2012; Jung and Casler 2006). Among the different methods available for lignin structural analysis, thioacidolysis followed by GC-MS analysis of the depolymerization monomers reveals both the proportion of the different constitutive units and the frequency of inter-unit linkages of the β aryl ether type. Indeed, thioacidolysis selectively cleaves these linkages, releasing monomers and oligomers only linked by resistant bonds. Yields of the different monomer types recovered after thioacidolysis, expressed with respect to lignin mass, gave indications as to the proportions of units linked by labile ether bonds. This structural parameter, in addition to giving an indication of the global lignin content, is likely to influence the cell wall properties and the bioconversion of lignocellulose. Indeed, Zhang et al. (2011) discovered a negative correlation between thioacidolysis yield and the enzymatic degradability of maize stems using a commercial cellulolytic cocktail.

All samples were found to have similar lignin structures with the presence of both guaiacyl (G) and syringyl (S) units, as in all angiosperms, with rather high S/G ratio (1.7) and total thioacidolysis yield (2000 to 2500 µmol/g). The S/G ratio was in the range of ratios previously observed for sunflower by high-throughput pyrolysis molecular beam mass spectrometry (1 to 2 for various H. annuus samples; Ziebell et al., 2013) and is close to that of most hardwoods (Dence and Lin, 1992). The thioacidolysis yield indicates an uncommonly high proportion of ether bonds, as observed for Eucalyptus globulus (Guerra et al., 2008). Considering that the average molar mass of a lignin unit is 200 g/mol, it can be calculated that about 50% of the units are only involved in aryl ether bonds. This suggests that such lignins are likely to depolymerize more easily than grass lignins, which contain lower proportions of aryl ether bonds. Indeed, aryl ether bonds are known as labile bonds, less resistant to chemical and biological attacks than other lignin inter-unit bonds. However, they may limit bioconversion of polysaccharides because of the barrier effect, as previously observed for maize (Zhang et al., 2011).

Table 2

Bacterial fatty acid content in cultures performed on arabinose, rapeseed straw (Rap1 and Rap2), and sunflower stalks (Sun1 and Sun2) (expressed as µg of fatty acid methyl esters per 3 × 108Streptomyces spores).

3.2.3 Polysaccharide composition

Glucose and xylose were the main neutral sugars recovered after acidic hydrolysis of rapeseed straw and sunflower stem samples (more than 90 wt % of the total neutral sugars). In addition to these two sugars, galactose, arabinose, and mannose were detected. Assuming that glucose is primarily derived from cellulose and other sugars from hemicelluloses, the cellulose and hemicellulose contents in the initial feedstocks and extraction residues were calculated as the anhydroglucose and total other anhydrosugar contents, respectively (Tab. 1). Little variation was observed between the different extraction residues, with cellulose content ranging from 30.4% to 34.3% and hemicelluloses content ranging from 14.4% to 18.2%. These values are in agreement with the data reported by Ziebell et al., (2013) for H. annuus (32.8% and 15.9%, respectively). The cellulose contents are lower than those reported by Mazhari Mousavi et al. (2013) for rapeseed straw and sunflower stalks as a result of the use of a different determination method. These authors did not determine the hemicellulose content.

3.2.4 Fatty acid composition

FA profiling of the lignocellulosic substrates was also conducted. Identification of the FA contained in these substrates was essential for further growth tests, as it was not possible to separate the bacterial biomass from the plant biomass (see below). FA quantification after growth tests was performed on bacterial-specific FA to exclude common FA from the quantification. FA profiling was done on 50 mg of freeze-dried, 1-mm lignocellulosic residues. It was observed that the samples contained saturated and unsaturated FA with lengths of 14 or more carbons (C14:0, C14:1, C16:0, C16:1, C18:0, C18:1, C18:2, C18:3, C20:0, and C22:0).

thumbnail Fig. 3

Fatty acid profiling of Streptomyces lividans grown on monosaccharides. After 6 d of culture at 30 °C in the presence of monosaccharides as the carbon source, Streptomyces cultures were freeze-dried and the samples were submitted to transmethylation. The FAME obtained on (A) arabinose, (B) glucose, and (C) xylose were analyzed using gas chromatography coupled with flame ionization detection (D) Relative fatty acid profiling was plotted for each carbon source. Abbreviations: FID, Flame Ionization Detection; FAME, fatty acid methyl esters; n.i., not identified.

3.3 Growth tests on lignocellulosic residues

3.3.1 Strain behavior

Streptomyces species have long been studied for their capacity to produce interesting bioactive molecules (antibiotics, anti-cancer and anti-obesity drugs, insecticides, herbicides, and others), but their ability to store TAG has been largely overlooked, even though ancient work reports this ability (Olukoshi and Packter, 1994). In a recently published work, it was observed that Streptomyces lividans TK24, which produces little to no antibiotics, has a better capacity to store TAG than Streptomyces coelicolor, a strong antibiotic producer (Le Marechal et al., 2013). For this reason, S. lividans TK 24 was selected to evaluate the feasibility of bioconversion of lignocellulose into bacterial lipids. Bacterial growth was assessed by evaluating the total bacterial FA content obtained after 6 days of cultivation. To do so, it was essential to identify the specific bacterial FA using various monosaccharides as substrates. FA analysis of bacteria grown on arabinose (Fig. 3A), glucose (Fig. 3B), and xylose (Fig. 3C) was performed to determine the variability of the FA profiles of cells grown on the various carbon sources. Gas chromatography revealed that the FA detected were the same for the three monosaccharides tested. According to their retention times, mostly branched-chain FA, anteiso-C15:0 and iso-C16:0, were identified, as previously described in the literature (Fig. 3D) (Arabolaza et al., 2008, 2010). Because FAs were also present in the lignocellulosic biomass (C14:0, C16:0, and C16:1), the latter could not be used for the evaluation of bacterial biomass production using lignocellulosic samples for growth.

thumbnail Fig. 4

Microscopic observation of Streptomyces mycelium on lignocellusosic residues. A few microliters of cultures were observed using a microscope equipped with Nomarski optics. Red arrows indicate Streptomyces mycelium adhering to the surface of the lignocellulosic residues.

3.3.2 Cultures on rapeseed and sunflower samples

Streptomyces cultures on 1-mm lignocellulosic samples (raw substrates, two independent cultures) and on residues obtained after extractions (one culture for each extraction) were performed. To assess the performance of the conversion of the carbon sources into lipids, culture was also performed on a reference medium containing arabinose, a carbon source known to be favorable for bacterial growth. After inoculation with the same amount of S. lividans spores, a negative control was collected for each substrate to perform fatty acid quantification at the starting point (Tab. 2). Cultivation was carried out for 6 days at 30 °C. Microscopic observation of the cultures revealed that the mycelium of Streptomyces adhered to the lignocellulosic substrate (Fig. 4) and consequently that it would not be possible to separate the Streptomyces from the lignocellulosic substrate for further biochemical analysis.

Quantification of total FA was performed on the whole cultures after transmethylation of the freeze-dried samples. C14:0, C16:0, and C16:1 FA were excluded from the analysis because they were common to both bacteria and lignocellulosic substrates. Some, C14:0 and C16:0, also seemed to be used as substrates by Streptomyces. The C12:0 FA was used as the internal standard for quantification because it was absent from both bacterial and lignocellulosic materials. First, it was observed that Streptomyces was able to use all of the lignocellulosic samples for growth, as an increase in the total bacterial FA content was observed between the negative control and the 6-days cultures (Tab. 2). Depending on the lignocellulosic sample used, the FA production ranged between 19% and 44% of the production obtained with the reference substrate, arabinose. Among the samples tested, the best performance was obtained with the unextracted Sun1 sample. This result can be explained by the specifically low lignin content of this sample (14%, versus 17% for the other samples). Indeed, because of their barrier properties and high content of ether bonds, the lignins present in the substrates were expected to limit the access of microorganisms to cellulose and hemicelluloses. The advantage of the Sun1 sample was lost after water extraction (Tab. 2), suggesting the water-extractible compounds present in this sample played a positive role in promoting bacterial growth. The absence of any difference between the water extraction residues and water-ethanol extraction residues for all samples indicated that the small proportion of ethanol-soluble compounds present in the samples did not affect growth or lipid production (Tab. 2).

4 Conclusions

Sunflower stalks and rape straw are two agricultural byproducts of interest but far less investigated until know than other lignocellulosic products. In this paper, we have provided novel information on the composition and lignin structure of these feedstocks which turned out to be very similar. Their lignins have high β-O-4 bond content compared to other angiosperms, which is an advantage with respect to lignin depolymerization process. For the first time, this pioneer work revealed that lignocellulosic products originating from oleaginous crops could be used as substrates for bacterial growth and production of lipids and fatty acids of interest in the actual context of green chemistry.

The authors declare that they have no competing interests.

Acknowledgments

We thank Imen Chaieb and Alexandre Cukier for their technical assistance. This project received financial support from PRES UniverSud (2011/11/PB/N°231) and from Organisation Nationale Interprofessionnelle des Graines et Fruits Oléagineux (ONIDOL 920P00 contract).

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Cite this article as: Thierry Dulermo, Fabien Coze, Marie-Joëlle Virolle, Valérie Méchin, Stéphanie Baumberger, Marine Froissard. Bioconversion of agricultural lignocellulosic residues into branched-chain fatty acids using Streptomyces lividans. OCL 2016, 23(2) A202.

All Tables

Table 1

Composition (% dry basis; mean (standard deviation)) and lignin characteristics of rapeseed straw (Brassica napus) and sunflower stalks (Helianthus annuus).

Table 2

Bacterial fatty acid content in cultures performed on arabinose, rapeseed straw (Rap1 and Rap2), and sunflower stalks (Sun1 and Sun2) (expressed as µg of fatty acid methyl esters per 3 × 108Streptomyces spores).

All Figures

thumbnail Fig. 1

Scheme of two-step accelerated solvent extraction (ASE) procedure for the recovery of water and water-ethanol total extractives.

In the text
thumbnail Fig. 2

Macroscopic observation of oleaginous lignocellulosic residues. Rapeseed straw (A, B) and sunflower stalk (C, D) agricultural residues were observed before (A, C) and after (B, D) grinding with a hammer mill to obtain residues with sizes compatible with biochemical analysis and Streptomyces growth tests.

In the text
thumbnail Fig. 3

Fatty acid profiling of Streptomyces lividans grown on monosaccharides. After 6 d of culture at 30 °C in the presence of monosaccharides as the carbon source, Streptomyces cultures were freeze-dried and the samples were submitted to transmethylation. The FAME obtained on (A) arabinose, (B) glucose, and (C) xylose were analyzed using gas chromatography coupled with flame ionization detection (D) Relative fatty acid profiling was plotted for each carbon source. Abbreviations: FID, Flame Ionization Detection; FAME, fatty acid methyl esters; n.i., not identified.

In the text
thumbnail Fig. 4

Microscopic observation of Streptomyces mycelium on lignocellusosic residues. A few microliters of cultures were observed using a microscope equipped with Nomarski optics. Red arrows indicate Streptomyces mycelium adhering to the surface of the lignocellulosic residues.

In the text

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