Name: fatty acid 13c isotopologue profiling provides insight into trophic carbon transfer and lipid metabolism of invertebrate consumers
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Description: Watch this Scientific Journal Video about Fatty Acid 13C Isotopologue Profiling Provides Insight into Trophic Carbon Transfer and Lipid Metabolism of Invertebrate Consumers at JoVE.com

The financial support of R. Menzel and L. Ruess by the Deutsche Forschungsgemeinschaft (RU RU780/11-1) is gratefully acknowledged. R. Nehring was funded by RU 780/10-1. Finally, we are extremely thankful to Dr. Hazel Ruvimbo Maboreke for proofreading our manuscript.

The described protocol does not fall under the competence of Animal Ethics. However, when people adapt the described protocols to higher animals, take care that the institutional Animal Ethics committee approved the protocol for animal handling.
1. Cultivation of Animals
NOTE: All explained experimental steps are based on well-established protocols26,27,28. Biotests in the la...

<ol>
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F., David, F., Brunengraber, H. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Correction+of+13C+mass+isotopomer+distributions+for+natural+stable+isotope+abundance.">Correction of 13C mass isotopomer distributions for natural stable isotope abundance.</a> J Mass Spectrom. 31 (3), 255-262 (1996).</li><li>Heuner, K., Eisenreich, W. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=The+intracellular+metabolism+of+legionella+by+isotopologue+profiling.">The intracellular metabolism of legionella by isotopologue profiling.</a> Methods Mol Biol. 954, 163-181 (2013).</li><li>Willenborg, J., et al. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Characterization+of+the+pivotal+carbon+metabolism+of+Streptococcus+suis+serotype+2+under+ex+vivo+and+chemically+defined+in+vitro+conditions+by+isotopologue+profiling.">Characterization of the pivotal carbon metabolism of Streptococcus suis serotype 2 under ex vivo and chemically defined in vitro conditions by isotopologue profiling.</a> J Biol Chem. 290 (9), 5840-5854 (2015).</li><li>Menzel, R., Ngosong, C., Ruess, L. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Isotopologue+profiling+enables+insights+into+dietary+routing+and+metabolism+of+trophic+biomarker+fatty+acids.">Isotopologue profiling enables insights into dietary routing and metabolism of trophic biomarker fatty acids.</a> Chemoecology. 27 (3), 101-114 (2017).</li><li>Buse, T., Ruess, L., Filser, J. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=New+trophic+biomarkers+for+Collembola+reared+on+algal+diets.">New trophic biomarkers for Collembola reared on algal diets.</a> Pedobiologia. 56 (3), 153-159 (2013).</li><li>Hutson, B. 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Isotopologue profiling
A detailed analysis of the quantitative aspects in 13C distribution in FAs needs cutting-edge technology to assign carbon partitioning in food webs. The present work employed isotopologue profiling to assess the 13C/12C ratios in common FA biomarkers for tropic interactions. This method is well established for amino acid analysis by liquid chromatography (LC-MS) and was applied for investigations of carbon metabolism in p...

In a cryptic habitat such as soil, trophic relationships are difficult to address and are further restricted by the small size of the fauna. The last decade has seen advances in biochemical ecology, particularly in the use of fatty acids as biomarkers for defining feeding strategies of the soil fauna under field conditions1,2,3. This is based on the fact that fatty acids from resources can be incorporated in consumer tissue as entire molecules, a process termed dietary routing4. Transfer of fatty acids has been reported over three trophic levels, i.e., from fungi to nematodes to Collembola5. Recently, the predatory fauna was considered6,7 and the first reviews on fatty acids as trophic markers in soil food webs have been published8,9.
More detailed information on trophic interactions is attained by fatty acid stable isotope probing (FA-SIP). The determination of 13C/12C ratios in fatty acids in diets and consumers can ascribe binary links and estimate the associated carbon flow, and has been employed in terrestrial, fresh water, and marine food webs10,11,12,13. The basic assumption is that dietary routed fatty acids are not subject to enzymatic processes; therefore, their 13C signal, i.e., the 13C/12C ratio of the fatty acid, in the consumer is similar to that in the diet1. However, a gradual depletion of the 13C signature up the food chain has been reported in aquatic systems, thereby hindering broad application of FA-SIP in trophic studies14,15,16. Moreover, knowledge in the lipid metabolism in most invertebrates in terrestrial food webs is still limited.
An understanding of the lipid metabolism pathways in consumers is essential for the usage of trophic marker fatty acids as means for the determination of the quantitative carbon flow in food web ecology. With this in mind, 13C-isotopologue profiling, which in principle can be applied for investigation of the carbon metabolism of any biological system17, is a promising method. Following the introduction of a 13C-labelled carbon substrate, the distribution of the 13C in the metabolic network is traceable since the generated metabolic products in the consumer show a specific isotopologue distribution. This can be assessed by quantitative nuclear metabolic resonance spectroscopy18,19 or mass spectrometry20,21, with the latter favored in biological samples with low biomass due to its higher sensitivity.
Although isotopologue profiling has been successfully applied to amino acids and provided insight into the in vivo carbon metabolism of bacterial pathogens17,22,23, its implementation in fatty acids has lagged behind. The first detailed analysis on the fate of a stable isotope labelled precursor fatty acid, its dietary routing or degradation via &#946;-oxidation, in soil invertebrate consumers, was recently performed by Menzel et al.24. Here, the methodological basics for incorporation experiments with 13C labelled fatty acids followed by isotopologue analysis of key descendants in frequent soil invertebrates, the Collembola, are provided. These microarthropods are a good model group as they form important components of the soil food web and are well investigated for their trophic marker fatty acids8,25.
An understanding of the lipid metabolism pathways in consumers is essential for the usage of trophic marker fatty acids as means for the determination of the quantitative carbon flow in food web ecology. The present protocol gives the design and set up for a laboratory feeding experiment, and the biochemical procedures for extraction and methylation of dominant lipids fractions (neutral lipids, phospholipids) from Collembola. It demonstrates how the isotopologue composition of fatty acids is analyzed by mass spectrometry and describes the related formula and calculations. This procedure results in: (i) the ratios of isotopologues exceeding the mass of the parent ion (i.e., the fatty acid molecular ion M+) by one or more mass units (M+1, M+2, M+3, etc.) and (ii) the overall 13C enrichment in fatty acids derived from the 13C labelled precursor. Although used for Collembola, this approach can generally be applied to any other predator-prey interaction on the premise that these are culturable in sufficient quantity under controlled conditions to ensure a successful label uptake and subsequent verification.

<table>
	<tbody>
		<tr>
			<td>neoLab-Round jars</td>
			<td>neoLab</td>
			<td>2-1506</td>
			<td>69 x 40 mm, 10 pacs/pack</td>
		</tr>
		<tr>
			<td>Charcoal activated</td>
			<td>Carl Roth</td>
			<td>X865.1</td>
			<td>p.a., powder, CAS No. 7440-44-0</td>
		</tr>
		<tr>
			<td>Alabaster Dental</td>
			<td>R&#214;HRICH-GIPSE</td>
			<td>---</td>
			<td>http://www.roehrich-gipse.de/dentalgipse.php</td>
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		<tr>
			<td>Chloroform</td>
			<td>Carl Roth</td>
			<td>7331.1</td>
			<td>HPLC &#8805; 99,9 %</td>
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		<tr>
			<td>Methanol</td>
			<td>Carl Roth</td>
			<td>P717.1</td>
			<td>HPLC &#8805; 99,9 %</td>
		</tr>
		<tr>
			<td>Hexan</td>
			<td>Carl Roth</td>
			<td>7339.1</td>
			<td>HPLC &#8805; 98 %</td>
		</tr>
		<tr>
			<td>tert-Butyl methyl ether (MTBE)</td>
			<td>Carl Roth</td>
			<td>T175.1</td>
			<td>HPLC &#8805; 99,5 %</td>
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		<tr>
			<td>Aceton</td>
			<td>Carl Roth</td>
			<td>7328.2</td>
			<td>HPLC &#8805; 99,9 %</td>
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		<tr>
			<td>NaOH</td>
			<td>Carl Roth</td>
			<td>6771.1</td>
			<td>p.a. &#8805;99 %, in pellets</td>
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		<tr>
			<td>di-Natriumhydrogenphosphat</td>
			<td>Carl Roth</td>
			<td>P030.1</td>
			<td>p.a. &#8805;99 % , water free</td>
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		<tr>
			<td>Na-dihydrogenphosphat Dihydrat</td>
			<td>Carl Roth</td>
			<td>T879.1</td>
			<td>p.a. &#8805;99 %</td>
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		<tr>
			<td>Hypochloric acid (6 N)</td>
			<td>VWR International</td>
			<td>26,115,000</td>
			<td>AVS TITRINORM vol. solution</td>
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		<tr>
			<td>Bond Elut (Columns)</td>
			<td>Agilent Tech.</td>
			<td>14102037</td>
			<td>HF Bond Elut-SI, 500 mg, 3 mL, 50/PK</td>
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		<tr>
			<td>Pr&#228;paratengl&#228;ser Duran</td>
			<td>Glasger&#228;tebau Ochs</td>
			<td>135215</td>
			<td>&#216; 16 x 100 mm, plus screw cap with handy knurl and integrated PTFE/silicone gasket</td>
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		<tr>
			<td>Supelco 37 Component FAME Mix</td>
			<td>Sigma-Aldrich</td>
			<td>47885-U Supelco</td>
			<td>10&#160;mg/mL in methylene chloride, analytical standard</td>
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		<tr>
			<td>FlowMesh</td>
			<td>Carl Roth</td>
			<td>2796.1</td>
			<td>Polypropylene mesh, approximately 0.3 mm thick, with 1 mm strand spacing</td>
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			<td>Bacterial Acid Methyl Ester (BAME) Mix</td>
			<td>Sigma-Aldrich</td>
			<td>47080-U Supelco</td>
			<td>10&#160;mg/mL in methyl caproate, analytical standard</td>
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		<tr>
			<td>Methyl nonadecanoate</td>
			<td>Sigma-Aldrich</td>
			<td>74208</td>
			<td>analytical standard &#8805; 98.0 %</td>
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		<tr>
			<td>Hexadecanoic acid-1-13C (Palmitic)</td>
			<td>Larodan Fine Chemicals</td>
			<td>78-1600</td>
			<td>GC &#8805; 98.0 % (13C: 99.0 %)</td>
		</tr>
		<tr>
			<td>RVC 2-25 CDplus</td>
			<td>Martin Christ Gefrier-trocknungsanlagen</td>
			<td></td>
			<td>Compact benchtop midi concentrator</td>
		</tr>
		<tr>
			<td>Alpha 2-4 LDplus</td>
			<td>Martin Christ Gefrier-trocknungsanlagen</td>
			<td></td>
			<td>Drying manifold</td>
		</tr>
		<tr>
			<td>MZ 2C NT</td>
			<td>Vacuubrand GMBH</td>
			<td></td>
			<td>Vacuum pump</td>
		</tr>
		<tr>
			<td>Roto-Shake Genie</td>
			<td>Scientific Industries</td>
			<td></td>
			<td>Combined rocking and rotating device</td>
		</tr>
		<tr>
			<td>XP64 Micro Comparator</td>
			<td>Mettler Toledo</td>
			<td></td>
			<td>Super high precision balance</td>
		</tr>
		<tr>
			<td>GC-System 7890A</td>
			<td>Agilent Tech.</td>
			<td></td>
			<td>Gas chromatograph</td>
		</tr>
		<tr>
			<td>7000 GC/MS Triple Quad</td>
			<td>Agilent Tech.</td>
			<td></td>
			<td>Triple Quad mass spectrometer</td>
		</tr>
		<tr>
			<td>7683B Series Injector</td>
			<td>Agilent Tech.</td>
			<td></td>
			<td>Sample injector</td>
		</tr>
		<tr>
			<td>Heraeus Multifuge 3SR+</td>
			<td>Thermo Scientific</td>
			<td></td>
			<td>Centrifuge with 10 ml tube rotor</td>
		</tr>
	</tbody>
</table>

fatty acid 13c isotopologue profiling provides insight into trophic carbon transfer and lipid metabolism of invertebrate consumers

Fatty acids (FAs) are useful biomarkers in food web ecology because they are typically assimilated as a complete molecule and transferred into consumer tissue with minor or no modification, allowing the dietary routing between different trophic levels. However, the FA trophic marker approach is still hampered by the limited knowledge in lipid metabolism of the soil fauna. This study used entirely labelled palmitic acid (13C16:0, 99 atom%) as a tracer in fatty acid metabolism pathways of two widespread soil Collembola, Protaphorura fimata and Heteromurus nitidus. In order to investigate the fate and metabolic modifications of this precursor, a method of isotopologue profiling is presented, performed by mass spectrometry using single ion monitoring. Moreover, the upstream laboratory feeding experiment is described, as well as the extraction and methylation of dominant lipid fractions (neutral lipids, phospholipids) and the related formula and calculations. Isotopologue profiling does not only yield the overall 13C enrichment in fatty acids derived from the 13C labeled precursor but also produces the pattern of isotopologues exceeding the mass of the parent ion (i.e., the FA molecular ion M+) of each labeled FA by one or more mass units (M+1, M+2, M+3, etc.). This knowledge allows conclusions on the ratio of dietary routing of an entirely consumed FA in comparison to de novo biosynthesis. The isotopologue profiling is suggested as a useful tool for evaluation of fatty acid metabolism in soil animals to disentangle trophic interactions.

Fresh weight and lipid content of Collembola 
In the course of the described experiment, the content in NLFAs and PLFAs did not change significantly over time, whereas the fresh weight of specimens increased slightly but not significantly24. Both parameters indicate a good level of physical fitness of the Collembola specimens. Be aware to investigate Collembola&#39;s fresh weight and lipid content throughout the experiment corresponding to the...

Watch this Scientific Journal Video about Fatty Acid 13C Isotopologue Profiling Provides Insight into Trophic Carbon Transfer and Lipid Metabolism of Invertebrate Consumers at JoVE.com

Fatty Acid 13C Isotopologue Profiling Provides Insight into Trophic Carbon Transfer and Lipid Metabolism of Invertebrate Consumers

The fatty acid trophic marker approach, i.e., the assimilation of fatty acids as entire molecule and transfer into consumer tissue with no or minor modification, is hampered by knowledge gaps in fatty acid metabolism of small soil invertebrates. Isotopologue profiling is provided as a valuable tool to disentangle trophic interactions.

Fatty Acid 13C Isotopologue Profiling Provides Insight into Trophic Carbon Transfer and Lipid Metabolism of Invertebrate Consumers

Fatty acids (FAs) are useful biomarkers in food web ecology because they are typically assimilated as a complete molecule and transferred into consumer ...

The overall goal of this isotopologue profiling is to follow the trophic transfer of dietary fatty acids in invertebrate consumers, including their processing and lipid metabolism, such as chain elongation or beta oxidation. This method can help answer key question in food web ecology, such as who's eating whom, a question not easy to answer in a cryptic ecosystem, such as soil. Demonstrating the technique will be Dilara Simsek, a master student from the lab of Professor Liliane Ruess.To prepare plastic microcosms with tight-fitting lids, in a plaster pot, mix nine parts of plaster of Paris and one part of dry activated charcoal. Add 10 parts of distilled water, and allow the mixture to sit at room temperature without stirring for five minutes. Use a lab spoon to stir the mixture in a clockwise direction at moderate speed to avoid air bubbles until a thick, soupy consistency is achieved.Then, pour the mixture into the microcosms to a height of about one centimeter. Smooth the plaster by gentle tapping on the bench and swirling. Note that holes from air bubbles and furrows, added with a sterile spatula, may encourage fertile Collembola to lay eggs there.However, this study avoided holes and furrows in favor of having the same reproducible conditions. After allowing the microcosms to dry and then moistening them, use a suction tube fitted with a small piece of mesh to transfer 30 freshly hatched Collembola to the plaster base of the microcosms. Provide about a knife tip's worth of granulated dry Baker's yeast as food, and renew it at least twice per week.Plan three independent replicates per sampling day. In this study, days zero to seven and 14 were sampled. Incubate the microcosms in the dark at 15 degrees Celsius, and maintain a constant temperature, as fatty acids are altered by animal metabolism to meet the requirements for membrane fluidity.To harvest animals, directly after weighing according to the text protocol, carefully transfer the animals from the scale pans into 10-milliliter glass test tubes. Use one milliliter of HPLC-grade methanol to fill the tubes, and store them at negative 20 degrees Celsius until analysis. After preparing three glass test tubes for each batch of samples and reducing the methanol applied to the samples for storage, add five milliliters of single-phase extraction solvent to each sample, including blanks, and extract the Collembolan lipids at room temperature by shaking at 200 rpm overnight.After extracting the samples according to the text protocol, to carry out fatty acid pattern analysis, precondition a silica acid column for each sample by adding two milliliters of chloroform to each column. After the chloroform has passed through the columns, use a glass Pasteur pipette to remove the lower chloroform phase from the samples. Then, transfer it to an individual column.Use five milliliters of chloroform to elute the neutral lipids, or NLFAs, in fractions into individual glass vessels. Then, use 10 milliliters of acetone to elute the glycolipids and five milliliters of methanol to elute the phospholipid fatty acids, or PLFAs. Following extraction, transfer the NLFA and PLFA open tubes to a rotational vacuum concentrator, or RVC, and evaporate the samples at 60 degrees Celsius in a vacuum of 24 hPa for approximately 90 minutes or until dry.After isolating and washing the fatty acid methyl esters, or FAMEs, use a glass Pasteur pipette to transfer the upper lipid-containing phase to a glass chromatography sample vial equipped with a Teflon septum. Encapsulate the vial, and store it at negative 20 degrees Celsius until analysis. To identify FAMEs in NFLA and PLFA samples, on a GC-FID, set up a sequence with the respective software of the instrument according to the manufacturer's instructions.Start the sequence with the external standard mixtures, followed by the samples. There will be slight delay in elution time of the fatty acids from the GC column with each run. Either include a standard every 10th run in the sample sequence, or use retention time locking for palmitic acid.Set the program, and calculate the nmol of fatty acid according to the text protocol. To carry out carbon-13 analysis by isotopologue profiling, use a polar capillary column, as it further allows the separation of unsaturated fatty acids, even with the same number of double bonds. The choice of the GC column is critical for the results, as it determines a good representation of the molecule ion in the fatty acids.For a DB-23 column, start oven temperature at 130 degrees Celsius, and increase it by 6.5 degrees Celsius per minute to 170 degrees Celsius. Follow with an increase of three degrees Celsius per minute to 203 degrees Celsius, and hold for 1.9 minutes. Then, proceed with an increase of 40 degrees Celsius per minute to 230 degrees Celsius, and hold for 8.3 minutes.Set the transfer line temperature to 280 degrees Celsius. After completing the program setup according to the text protocol, determine carbon-13 incorporation in the molecular ion of fatty acids by first running an initial scan to see what is present. Then, run selected ion monitoring, or SIM, on the appropriate ions, and acquire data at molecular masses of interest by selecting m/z scan windows, or SIM groups, encompassing the chromatographic peak time of the respective fatty acid.Typically, monitor two to four ions per analyte and time window. For mass development, we use total ion counts with external fatty acid standards. Based on their retention time and fragment ions, time segments are chosen.Detect the molecular ion, M plus, of the respective fatty acid and all its isotopologues, M plus one, M plus two, et cetera. Assign trophic carbon flux, the position of carbon-13 incorporation, and calculate carbon-13 enrichment according to the text protocol. This figure presents a SIM-MS spectrum of pure 16-to-zero palmitic acid.The natural abundance of carbon-13 in this compound becomes detectable by the presence of M plus one and M plus two isotopologues in addition to the molecular ion M plus. By comparison, this spectrogram represents the entire labeled palmitic acid. Here, the sole occurrence of the ion M plus 16 reflects the high purity of the synthetically labeled compound.The following SIM scans are derived from four dominant fatty acids in the PLFA fraction of Heteromurus nitidus at the first sampling day after labeling. The assimilation of the labeled marker molecule into palmitic acid becomes visible by the abundance of the M plus 16 isotopologue, as it represents the entire labeled fatty acid. Furthermore, desaturation of 16 to zero or elongation plus desaturation can be assigned.Thereby, the detection of isotopologues bigger than M plus 16, for example, M plus 17 and M plus 18, demonstrate chain elongation of the labeled precursor 16 to zero by the use of C2-13 fragments. Presented here, are the relative portions of the ions M plus one to M plus three and M plus 16 to M plus 20 of the five most heavily labeled NLFA and PLFA from Protaphorura fimata, estimated on day zero and day one. While attempting this procedure, it is important to remember that consumers naturally comprise certain C isotopes.This amount must be determined in control experiments without label diet. This natural certain C signal send subtracted as background from the label templates. Don't forget that working with solvent can be extremely hazardous, and precautions should be taken.

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Research

JoVE Journal

Biochemistry

Identification of Fatty Acids in Bacillus cereus

The Bacillus species contain branched chain and unsaturated fatty acids (FAs) with diverse positions of the methyl branch (iso or anteiso) and of the double bond. Changes in FA composition play a crucial role in the adaptation of bacteria to their environment. These modifications entail a change in the ratio of iso versus anteiso branched FAs, and in the proportion of unsaturated FAs relative to saturated FAs, with double bonds created at specific positions. Precise identification of the FA profile is necessary to understand the adaptation mechanisms of Bacillus species.
Many of the FAs from Bacillus are not commercially available. The strategy proposed herein identifies FAs by combining information on the retention time (by calculation of the equivalent chain length (ECL)) with the mass spectra of three types of FA derivatives: fatty acid methyl esters (FAMEs), 4,4-dimethyl oxazoline derivatives (DMOX), and 3-pyridylcarbinyl ester (picolinyl). This method can identify the FAs without the need to purify the unknown FAs.
Comparing chromatographic profiles of FAME prepared from Bacillus cereus with a commercial mixture of standards allows for the identification of straight-chain saturated FAs, the calculation of the ECL, and hypotheses on the identity of the other FAs. FAMEs of branched saturated FAs, iso or anteiso, display a constant negative shift in the ECL, compared to linear saturated FAs with the same number of carbons. FAMEs of unsaturated FAs can be detected by the mass of their molecular ions, and result in a positive shift in the ECL compared to the corresponding saturated FAs.
The branching position of FAs and the double bond position of unsaturated FAs can be identified by the electron ionization mass spectra of picolinyl and DMOX derivatives, respectively. This approach identifies all the unknown saturated branched FAs, unsaturated straight-chain FAs and unsaturated branched FAs from the B. cereus extract.

Identification of Fatty Acids in Bacillus cereus

We propose a protocol to identify fatty acids without the need to purify them. It combines information on the retention times with the mass spectra of three types of fatty acid derivatives: fatty acid methyl esters (FAMEs), 4,4-dimethyl oxazoline derivatives (DMOX), and 3-pyridylcarbinyl esters (picolinyl).

The Bacillus species contain branched chain and unsaturated fatty acids (FAs) with diverse positions of the methyl branch (iso or anteiso) and of the ...

Detergent-free Ultrafast Reconstitution of Membrane Proteins into Lipid Bilayers Using Fusogenic Complementary-charged Proteoliposomes.

Detergents are indispensable for delivery of membrane proteins into 30-100 nm small unilamellar vesicles, while more complex, larger model lipid bilayers are less compatible with detergents.
Here we describe a strategy for bypassing this fundamental limitation using fusogenic oppositely charged liposomes bearing a membrane protein of interest. Fusion between such vesicles occurs within 5 min in a low ionic strength buffer. Positively charged fusogenic liposomes can be used as simple shuttle vectors for detergent-free delivery of membrane proteins into biomimetic target lipid bilayers, which are negatively charged. We also show how to reconstitute membrane proteins into fusogenic proteoliposomes with a fast 30-min protocol.
Combining these two approaches, we demonstrate a fast assembly of an electron transport chain consisting of two membrane proteins from E. coli, a primary proton pump bo3-oxidase and F1Fo ATP synthase, in membranes of vesicles of various sizes, ranging from 0.1 to &#62;10 microns, as well as ATP production by this chain.

Here we present two ultrafast protocols for reconstitution of membrane proteins into fusogenic proteoliposomes, and fusion of such proteoliposomes with target lipid bilayers for detergent-free delivery of these membrane proteins into the postfusion bilayer. The combination of these approaches enables fast and easily controlled assembly of complex multi-component membrane systems.

Detergents are indispensable for delivery of membrane proteins into 30-100 nm small unilamellar vesicles, while more complex, larger model lipid bilayers ...

Sampling and Pretreatment of Tooth Enamel Carbonate for Stable Carbon and Oxygen Isotope Analysis

Stable carbon and oxygen isotope analysis of human and animal tooth enamel carbonate has been applied in paleodietary, paleoecological, and paleoenvironmental research from recent historical periods back to over 10 million years ago. Bulk approaches provide a representative sample for the period of enamel mineralization, while sequential samples within a tooth can track dietary and environmental changes during this period. While these methodologies have been widely applied and described in archaeology, ecology, and paleontology, there have been no explicit guidelines to aid in the selection of necessary lab equipment and to thoroughly describe detailed laboratory sampling and protocols. In this article, we document textually and visually, the entire process from sampling through pretreatment and diagenetic screening to make the methodology more widely available to researchers considering its application in a variety of laboratory settings.

Stable carbon and oxygen isotope analysis of human and animal tooth enamel carbonate has been used as a proxy for individual diet and environmental reconstruction. Here, we provide a detailed description and visual documentation of bulk and sequential tooth enamel sampling as well as pretreatment of archaeological and paleontological samples.

Stable carbon and oxygen isotope analysis of human and animal tooth enamel carbonate has been applied in paleodietary, paleoecological, and ...

Nitropeptide Profiling and Identification Illustrated by Angiotensin II

Protein nitration is one of the most important post-translational modifications (PTM) on tyrosine residues and it can be induced by chemical actions of reactive oxygen species (ROS) and reactive nitrogen species (RNS) in eukaryotic cells. Precise identification of nitration sites on proteins is crucial for understanding the physiological and pathological processes related to protein nitration, such as inflammation, aging, and cancer. Since the nitrated proteins are of low abundance in cells even under induced conditions, no universal and efficient methods have been developed for the profiling and identification of protein nitration sites. Here we describe a protocol for nitropeptide enrichment by using a chemical reduction reaction and biotin labeling, followed by high resolution mass spectrometry. In our method, nitropeptide derivatives can be identified with high accuracy. Our method exhibits two advantages compared to the previously reported methods. First, dimethyl labeling is used to block the primary amine on nitropeptides, which can be used to generate quantitative results. Second, a disulfide bond containing NHS-biotin reagent is used for the enrichment, which can be further reduced and alkylated to enhance the detection signal on a mass spectrometer. This protocol has been successfully applied to the model peptide Angiotensin II in the current paper.

Proteomic profiling of tyrosine-nitrated proteins has been a challenging technique due to the low abundance of the 3-nitrotyrosine modification. Here we describe a novel approach for nitropeptide enrichment and profiling by using Angiotensin II as the model. This method can be extended for other in vitro or in vivo systems.

Protein nitration is one of the most important post-translational modifications (PTM) on tyrosine residues and it can be induced by chemical actions of ...

Isolation of Lipoprotein Particles from Chicken Egg Yolk for the Study of Bacterial Pathogen Fatty Acid Incorporation into Membrane Phospholipids

Staphylococcus aureus and other Gram-positive pathogens incorporate fatty acids from the environment into membrane phospholipids. During infection, the majority of exogenous fatty acids are present within host lipoprotein particles. Uncertainty remains as to the reservoirs of host fatty acids and the mechanisms by which bacteria extract fatty acids from the lipoprotein particles. In this work, we describe protocols for enrichment of low-density lipoprotein (LDL) particles from chicken egg yolk and determining whether LDLs serve as fatty acid reservoirs for S. aureus. This method exploits unbiased lipidomic analysis and chicken LDLs, an effective and economical model for the exploration of interactions between LDLs and bacteria. The analysis of S. aureus integration of exogenous fatty acids from LDLs is performed using high-resolution/accurate mass spectrometry and tandem mass spectrometry, enabling the characterization of the fatty acid composition of the bacterial membrane and unbiased identification of novel combinations of fatty acids that arise in bacterial membrane lipids upon exposure to LDLs. These advanced mass spectrometry techniques offer an unparalleled perspective of fatty acid incorporation by revealing the specific exogenous fatty acids incorporated into the phospholipids. The methods outlined here are adaptable to the study of other bacterial pathogens and alternative sources of complex fatty acids.

This method provides a framework for studying incorporation of exogenous fatty acids from complex host sources into bacterial membranes, particularly Staphylococcus aureus. To achieve this, protocols for the enrichment of lipoprotein particles from chicken egg yolk and subsequent fatty acid profiling of bacterial phospholipids utilizing mass spectrometry are described.

Staphylococcus aureus and other Gram-positive pathogens incorporate fatty acids from the environment into membrane phospholipids. During infection, the ...

Detergent-assisted Reconstitution of Recombinant Drosophila Atlastin into Liposomes for Lipid-mixing Assays

Membrane fusion is a crucial process in the eukaryotic cell. Specialized proteins are necessary to catalyze fusion. Atlastins are endoplasmic reticulum (ER) resident proteins implicated in homotypic fusion of the ER. We detail here a method for purifying a glutathione S-transferase (GST) and poly-histidine tagged Drosophila atlastin by two rounds of affinity chromatography. Studying fusion reactions in vitro requires purified fusion proteins to be inserted into a lipid bilayer. Liposomes are ideal model membranes, as lipid composition and size may be adjusted. To this end, we describe a reconstitution method by detergent removal for Drosophila atlastin into preformed liposomes. While several reconstitution methods are available, reconstitution by detergent removal has several advantages that make it suitable for atlastins and other similar proteins. The advantage of this method includes a high reconstitution yield and correct orientation of the reconstituted protein. This method can be extended to other membrane proteins and for other applications that require proteoliposomes. Additionally, we describe a FRET based lipid mixing assay of proteoliposomes used as a measurement of membrane fusion.

Detergent-assisted Reconstitution of Recombinant Drosophila Atlastin into Liposomes for Lipid-mixing Assays

Biological membrane fusion is catalyzed by specialized fusion proteins. Measuring the fusogenic properties of proteins can be achieved by lipid mixing assays. We present a method for purifying recombinant Drosophila atlastin, a protein that mediates homotypic fusion of the ER, reconstituting it to preformed liposomes, and testing for fusion capacity.

Membrane fusion is a crucial process in the eukaryotic cell. Specialized proteins are necessary to catalyze fusion. Atlastins are endoplasmic reticulum ...

Optimized Incorporation of Alkynyl Fatty Acid Analogs for the Detection of Fatty Acylated Proteins using Click Chemistry

Fatty acylation, the covalent addition of saturated fatty acids to protein substrates, is important in regulating a myriad of cellular functions in addition to its implications in cancer and neurodegenerative diseases. Recent developments in fatty acylation detection methods have enabled efficient and non-hazardous detection of fatty acylated proteins, particularly through the use of click chemistry with bio-orthogonal labeling. However, click chemistry detection can be limited by the poor solubility and potential toxic effects of adding long chain fatty acids to cell culture. Described here is a labeling approach with optimized delivery using saponified fatty acids in combination with fatty-acid free BSA, as well as delipidated media, which can improve detection of hard to detect fatty acylated proteins. This effect was most pronounced with the alkynyl-stearate analog, 17-ODYA, which has been the most commonly used fatty acid analog in click chemistry detection of acylated proteins. This modification will improve cellular incorporation and increase sensitivity to acylated protein detection. In addition, this approach can be applied in a variety of cell types and combined with other assays such as pulse-chase analysis, stable isotope labeling with amino acids in cell culture, and mass spectrometry for quantitative profiling of fatty acylated proteins.

The study of fatty acylation has important implications in cellular protein interactions and diseases. Presented here is a modified protocol to improve click chemistry detection of fatty acylated proteins, which can be applied in various cell types and combined with other assays, including pulse-chase and mass spectrometry.

Fatty acylation, the covalent addition of saturated fatty acids to protein substrates, is important in regulating a myriad of cellular functions in ...

Ganglioside Extraction, Purification and Profiling

Gangliosides are glycosphingolipids that contain one or more sialic acid residues. They are found on all vertebrate cells and tissues but are especially abundant in the brain. Expressed primarily on the outer leaflet of the plasma membranes of cells, they modulate the activities of cell surface proteins via lateral association, act as receptors in cell-cell interactions and are targets for pathogens and toxins. Genetic dysregulation of ganglioside biosynthesis in humans results in severe congenital nervous system disorders. Because of their amphipathic nature, extraction, purification, and analysis of gangliosides require techniques that have been optimized by many investigators in the 80 years since their discovery. Here, we describe bench-level methods for the extraction, purification, and preliminary qualitative and quantitative analyses of major gangliosides from tissues and cells that can be completed in a few hours. We also describe methods for larger scale isolation and purification of major ganglioside species from brain. Together, these methods provide analytical and preparative scale access to this class of bioactive molecules.

Gangliosides are sialic acid-bearing glycosphingolipids that are particularly abundant in the brain. Their amphipathic nature requires organic/aqueous extraction and purification techniques to ensure optimal recovery and accurate analyses. This article provides overviews of analytic and preparative scale ganglioside extraction, purification, and thin layer chromatography analysis.

Gangliosides are glycosphingolipids that contain one or more sialic acid residues. They are found on all vertebrate cells and tissues but are especially ...

Measurement of Fatty Acid &#946;-Oxidation in a Suspension of Freshly Isolated Mouse Hepatocytes

Fatty acid &#946;-oxidation is a key metabolic pathway to meet the energy demands of the liver and provide substrates and cofactors for additional processes, such as ketogenesis and gluconeogenesis, which are essential to maintain whole-body glucose homeostasis and support extra-hepatic organ function in the fasted state. Fatty acid &#946;-oxidation occurs within the mitochondria and peroxisomes and is regulated through multiple mechanisms, including the uptake and activation of fatty acids, enzyme expression levels, and availability of cofactors such as coenzyme A and NAD+. In assays that measure fatty acid &#946;-oxidation in liver homogenates, cell lysis and the common addition of supraphysiological levels of cofactors mask the effects of these regulatory mechanisms. Furthermore, the integrity of the organelles in the homogenates is hard to control and can vary significantly between preparations. The measurement of fatty acid &#946;-oxidation in intact primary hepatocytes overcomes the above pitfalls. This protocol describes a method for the measurement of fatty acid &#946;-oxidation in a suspension of freshly isolated primary mouse hepatocytes incubated with 14C-labeled palmitic acid. By avoiding hours to days of culture, this method has the advantage of better preserving the protein expression levels and metabolic pathway activity of the original liver, including the activation of fatty acid &#946;-oxidation observed in hepatocytes isolated from fasted mice compared to fed mice.

Measurement of Fatty Acid &amp;#946;-Oxidation in a Suspension of Freshly Isolated Mouse Hepatocytes

Fatty acid &#946;-oxidation is an essential metabolic pathway responsible for generating energy in many different cell types, including hepatocytes. Here, we describe a method to measure fatty acid &#946;-oxidation in freshly isolated primary hepatocytes using 14C-labeled palmitic acid.

Fatty acid &#946;-oxidation is a key metabolic pathway to meet the energy demands of the liver and provide substrates and cofactors for additional ...

Assessing Hepatic Steatosis with 3D Fluorescence Lipid Droplet Reconstruction

Analysis of Fluorescent-Stained Lipid Droplets with 3D Reconstruction for Hepatic Steatosis Assessment

Lipid droplets (LDs) are specialized organelles that mediate lipid storage and play a very important role in suppressing lipotoxicity and preventing dysfunction caused by free fatty acids (FAs). The liver, given its critical role in the body's fat metabolism, is persistently threatened by the intracellular accumulation of LDs in the form of both microvesicular and macrovesicular hepatic steatosis. The histologic characterization of LDs is typically based on lipid-soluble diazo dyes, such as Oil Red O (ORO) staining, but a number of disadvantages consistently hamper the use of this analysis with liver specimens. More recently, lipophilic fluorophores 493/503 have become popular for visualizing and locating LDs due to their rapid uptake and accumulation into the neutral lipid droplet core. Even though most applications are well-described in cell cultures, there is less evidence demonstrating the reliable use of lipophilic fluorophore probes as an LD imaging tool in tissue samples. Herein, we propose an optimized boron dipyrromethene (BODIPY) 493/503-based protocol for the evaluation of LDs in liver specimens from an animal model of high-fat diet (HFD)-induced hepatic steatosis. This protocol covers liver sample preparation, tissue sectioning, BODIPY 493/503 staining, image acquisition, and data analysis. We demonstrate an increased number, intensity, area ratio, and diameter of hepatic LDs upon HFD feeding. Using orthogonal projections and 3D reconstructions, it was possible to observe the full content of neutral lipids in the LD core, which appeared as nearly spherical droplets. Moreover, with the fluorophore BODIPY 493/503, we were able to distinguish microvesicles (1 &#181;m &lt; d &#8804; 3 &#181;m), intermediate vesicles (3 &#181;m &lt; d &#8804; 9 &#181;m), and macrovesicles (d &gt; 9 &#181;m), allowing the successful discrimination of microvesicular and macrovesicular steatosis. Overall, this BODIPY 493/503 fluorescence-based protocol is a reliable and simple tool for hepatic LD characterization and may represent a complementary approach to the classical histological protocols.

Author Spotlight: Analysis of Fluorescent-Stained Lipid Droplets with 3D Reconstruction for Hepatic Steatosis Assessment  

Herein, we demonstrate an optimized BODIPY 493/503 fluorescence-based protocol for lipid droplet characterization in liver tissue. Through the use of orthogonal projections and 3D reconstructions, the fluorophore allows for successful discrimination between microvesicular and macrovesicular steatosis and may represent a complementary approach to the classical histological protocols for hepatic steatosis assessment.

Lipid droplets (LDs) are specialized organelles that mediate lipid storage and play a very important role in suppressing lipotoxicity and preventing ...