Summary of Study ST003278

This data is available at the NIH Common Fund's National Metabolomics Data Repository (NMDR) website, the Metabolomics Workbench, https://www.metabolomicsworkbench.org, where it has been assigned Project ID PR002032. The data can be accessed directly via it's Project DOI: 10.21228/M8ZC0C This work is supported by NIH grant, U2C- DK119886.

See: https://www.metabolomicsworkbench.org/about/howtocite.php

This study contains a large results data set and is not available in the mwTab file. It is only available for download via FTP as data file(s) here.

Study ID	ST003278
Study Title	Metabolomic analysis of Axon Regeneration in Xenopus laevis Retina
Study Summary	We profile the metabolite changes in the retina of a transgenic line of 1 year old Xenopus laevis Tg(islet2b:gfp) frogs that either had a monocular surgery of either a left optic crush injury (crush) or sham surgery (sham). The matching controls of uninjured right optic nerves were also collected (control). Tg(islet2b:gfp) frogs were allowed to recover for 12 and 27 days post optic nerve crush. Following euthanasia, the tissues were collected for metabolomic analysis. Samples were pooled for each category (crush, sham, and control) at n =3 to obtain sufficient metabolite concentrations for analysis. Metabolites were extracted using a Precellys Homogenizer and a serial extraction method: (1) 1:1 Methanol/Water and (2) 8:1:1 Acetonitrile/Methanol/Acetone. Metabolites were analyzed by untargeted liquid chromatography-mass spectrometry (LC MS-MS) profiling using a Q-Exactive Orbitrap instrument coupled with Vanquish Horizon Binary UHPLC LC-MS system. Metabolites were identified and quantified using Compound Discoverer 3.3 and isotopic internal metabolites standards.
Institute	University of Miami
Department	McKnight - Ophthalmology
Laboratory	Bhattacharya Lab
Last Name	Bhattacharya
First Name	Sanjoy
Address	1638 NW 10th Avenue, Room 706-A, Miami, FL 33136
Email	sbhattacharya@med.miami.edu
Phone	3054824103
Submit Date	2024-02-09
Raw Data Available	Yes
Raw Data File Type(s)	raw(Thermo)
Analysis Type Detail	LC-MS
Release Date	2024-07-15
Release Version	1

Select appropriate tab below to view additional metadata details:

Project:

Project ID:	PR002032
Project DOI:	doi: 10.21228/M8ZC0C
Project Title:	Metabolomic Analysis of Axon Regeneration in Xenopus laevis
Project Summary:	CNS injuries of the anuran amphibian, Xenopus laevis, are uniquely befitted for studying the molecular compositions of neuronal regeneration of retinal ganglion cells (RGC) due to a functional recovery of optic axons disparate to adult mammalian analogues. RGCs and their optic nerve axons undergo irreversible neurodegeneration in glaucoma and associated optic neuropathies, resulting in blindness in mammals. Conversely, Xenopus demonstrates RGC lifetime-spanning regenerative capabilities after optic nerve crush, inciting opportunities to compare de novo regeneration and develop efficient pharmaceutical approaches for vision restoration. Studies revealing metabolome alterations during optic nerve regeneration are sparse and could serve as a solid foundation for these underlying molecular changes. We profile the metabolite changes in the optic tissues of a transgenic line of 1 year old Xenopus laevis Tg(islet2b:gfp) frogs that either had a monocular surgery of either a left optic crush injury (crush) or sham surgery (sham). The matching controls of uninjured right optic nerves were also collected (control). Tg(islet2b:gfp) frogs were allowed to recover for 12 and 27 days post optic nerve crush. Following euthanasia, the tissues were collected for metabolomic analysis. Samples were pooled for each category (crush, sham, and control) at n =3 to obtain sufficient metabolite concentrations for analysis. Metabolites were extracted using a Precellys Homogenizer and a serial extraction method: (1) 1:1 Methanol/Water and (2) 8:1:1 Acetonitrile/Methanol/Acetone. Metabolites were analyzed by untargeted liquid chromatography-mass spectrometry (LC MS-MS) profiling using a Q-Exactive Orbitrap instrument coupled with Vanquish Horizon Binary UHPLC LC-MS system. Metabolites were identified and quantified using Compound Discoverer 3.3 and isotopic internal metabolites standards.
Institute:	University of Miami
Department:	McKnight - Ophthalmology
Laboratory:	Bhattacharya Lab
Last Name:	Bhattacharya
First Name:	Sanjoy
Address:	1638 NW 10th Avenue, Room 706-A, Miami, FL 33136
Email:	sbhattacharya@med.miami.edu
Phone:	3054824103

Subject:

Subject ID:	SU003398
Subject Type:	Amphibian
Subject Species:	Xenopus laevis
Taxonomy ID:	8355
Gender:	Not applicable

Factors:

Subject type: Amphibian; Subject species: Xenopus laevis (Factor headings shown in green)

mb_sample_id	local_sample_id	Sample source	Treatment
SA354787	Blank_NEG3	NA	Extraction Blank
SA354788	Blank_NEG2	NA	Extraction Blank
SA354789	Blank_NEG1	NA	Extraction Blank
SA354790	Blank_POS3	NA	Extraction Blank
SA354791	Blank_POS2	NA	Extraction Blank
SA354792	Blank_POS1	NA	Extraction Blank
SA354793	CTL_27dpi_Ret3_POS2	Retina	Control
SA354794	CTL_27dpi_Ret2_NEG2	Retina	Control
SA354795	CTL_27dpi_Ret2_NEG3	Retina	Control
SA354796	CTL_27dpi_Ret3_POS1	Retina	Control
SA354797	CTL_27dpi_Ret3_NEG3	Retina	Control
SA354798	CTL_27dpi_Ret3_POS3	Retina	Control
SA354799	CTL_27dpi_Ret3_NEG1	Retina	Control
SA354800	CTL_27dpi_Ret3_NEG2	Retina	Control
SA354801	CTL_27dpi_Ret2_POS3	Retina	Control
SA354802	CTL_12dpi_Ret1_POS2	Retina	Control
SA354803	CTL_27dpi_Ret2_NEG1	Retina	Control
SA354804	CTL_12dpi_Ret1_POS1	Retina	Control
SA354805	CTL_27dpi_Ret2_POS2	Retina	Control
SA354806	CTL_12dpi_Ret2_NEG1	Retina	Control
SA354807	CTL_27dpi_Ret2_POS1	Retina	Control
SA354808	CTL_12dpi_Ret2_POS2	Retina	Control
SA354809	CTL_12dpi_Ret2_POS1	Retina	Control
SA354810	CTL_12dpi_Ret1_NEG2	Retina	Control
SA354811	CTL_12dpi_Ret1_NEG1	Retina	Control
SA354812	CTL_12dpi_Ret1_POS3	Retina	Control
SA354813	CTL_12dpi_Ret1_NEG3	Retina	Control
SA354814	CTL_12dpi_Ret2_NEG2	Retina	Control
SA354815	CTL_27dpi_Ret1_NEG1	Retina	Control
SA354816	CTL_12dpi_Ret2_NEG3	Retina	Control
SA354817	CTL_27dpi_Ret1_NEG3	Retina	Control
SA354818	CTL_27dpi_Ret1_NEG2	Retina	Control
SA354819	CTL_12dpi_Ret2_POS3	Retina	Control
SA354820	CTL_27dpi_Ret1_POS3	Retina	Control
SA354821	CTL_27dpi_Ret1_POS2	Retina	Control
SA354822	CTL_27dpi_Ret1_POS1	Retina	Control
SA354823	CX_27dpi_Ret2_POS1	Retina	Crush
SA354824	CX_27dpi_Ret3_NEG1	Retina	Crush
SA354825	CX_27dpi_Ret3_POS3	Retina	Crush
SA354826	CX_27dpi_Ret3_POS2	Retina	Crush
SA354827	CX_27dpi_Ret3_POS1	Retina	Crush
SA354828	CX_27dpi_Ret2_NEG3	Retina	Crush
SA354829	CX_27dpi_Ret2_NEG2	Retina	Crush
SA354830	CX_27dpi_Ret2_NEG1	Retina	Crush
SA354831	CX_27dpi_Ret2_POS3	Retina	Crush
SA354832	CX_27dpi_Ret3_NEG2	Retina	Crush
SA354833	CX_27dpi_Ret3_NEG3	Retina	Crush
SA354834	CX_27dpi_Ret1_NEG3	Retina	Crush
SA354835	CX_12dpi_Ret2_POS1	Retina	Crush
SA354836	CX_12dpi_Ret1_POS1	Retina	Crush
SA354837	CX_12dpi_Ret1_POS2	Retina	Crush
SA354838	CX_12dpi_Ret1_POS3	Retina	Crush
SA354839	CX_12dpi_Ret1_NEG1	Retina	Crush
SA354840	CX_12dpi_Ret1_NEG2	Retina	Crush
SA354841	CX_12dpi_Ret1_NEG3	Retina	Crush
SA354842	CX_27dpi_Ret1_NEG2	Retina	Crush
SA354843	CX_27dpi_Ret2_POS2	Retina	Crush
SA354844	CX_12dpi_Ret2_POS2	Retina	Crush
SA354845	CX_12dpi_Ret2_NEG1	Retina	Crush
SA354846	CX_27dpi_Ret1_NEG1	Retina	Crush
SA354847	CX_27dpi_Ret1_POS3	Retina	Crush
SA354848	CX_27dpi_Ret1_POS2	Retina	Crush
SA354849	CX_27dpi_Ret1_POS1	Retina	Crush
SA354850	CX_12dpi_Ret2_NEG3	Retina	Crush
SA354851	CX_12dpi_Ret2_NEG2	Retina	Crush
SA354852	CX_12dpi_Ret2_POS3	Retina	Crush
SA354853	Pooled_QC2_MS1_Ret_NEG2	Retina	QC
SA354854	Pooled_QC2_MS1_Ret_POS2	Retina	QC
SA354855	Pooled_QC2_MS1_Ret_POS1	Retina	QC
SA354856	Pooled_QC1_MS1_Ret_NEG2	Retina	QC
SA354857	Pooled_QC1_MS1_Ret_NEG1	Retina	QC
SA354858	Pooled_QC2_MS1_Ret_NEG1	Retina	QC
SA354859	Pooled_QC1_MS1_Ret_POS1	Retina	QC
SA354860	Pooled_QC1_MS1_Ret_POS2	Retina	QC
SA354861	Left_Ret_SHAM2_NEG2	Retina	Sham
SA354862	Right_Ret_SHAM2_POS3	Retina	Sham
SA354863	Left_Ret_SHAM1_POS1	Retina	Sham
SA354864	Left_Ret_SHAM1_POS2	Retina	Sham
SA354865	Left_Ret_SHAM1_POS3	Retina	Sham
SA354866	Left_Ret_SHAM1_NEG1	Retina	Sham
SA354867	Left_Ret_SHAM1_NEG2	Retina	Sham
SA354868	Left_Ret_SHAM1_NEG3	Retina	Sham
SA354869	Right_Ret_SHAM2_NEG3	Retina	Sham
SA354870	Right_Ret_SHAM2_NEG2	Retina	Sham
SA354871	Right_Ret_SHAM2_NEG1	Retina	Sham
SA354872	Right_Ret_SHAM2_POS2	Retina	Sham
SA354873	Left_Ret_SHAM2_NEG1	Retina	Sham
SA354874	Left_Ret_SHAM2_NEG3	Retina	Sham
SA354875	Right_Ret_SHAM1_NEG3	Retina	Sham
SA354876	Right_Ret_SHAM1_NEG2	Retina	Sham
SA354877	Right_Ret_SHAM1_NEG1	Retina	Sham
SA354878	Right_Ret_SHAM1_POS3	Retina	Sham
SA354879	Right_Ret_SHAM1_POS2	Retina	Sham
SA354880	Right_Ret_SHAM1_POS1	Retina	Sham
SA354881	Left_Ret_SHAM2_POS1	Retina	Sham
SA354882	Left_Ret_SHAM2_POS2	Retina	Sham
SA354883	Left_Ret_SHAM2_POS3	Retina	Sham
SA354884	Right_Ret_SHAM2_POS1	Retina	Sham

Showing results 1 to 98 of 98

Showing results 1 to 98 of 98

Collection:

Collection ID:	CO003391
Collection Summary:	The tissue was removed via dissection from the optic nerve head to the optic chiasm. The retinas were collected at 12- and 27-days post crush and separated into biological samples. Due to the small tissue and metabolomics resolution constraints, tissues were pooled to generate higher signal intensities. A total of 3 retinas were pooled into one tube.
Sample Type:	Eye tissue

Treatment:

Treatment ID:	TR003407
Treatment Summary:	Optic nerves from each transgenic Tg(Islet2b:EGFP-RPL10a) Xenopus laevis frogs, 3.5 - 5.0 cm in length, underwent monocular surgery of either a left optic crush injury (crush) or sham surgery (sham). The matching controls of uninjured right optic nerves were also collected (control). Operated individuals were anesthetized with 0.05% ethyl 3-aminobenzoate methanesulfonate (Sigma, USA).

Sample Preparation:

Sampleprep ID:	SP003405
Sampleprep Summary:	Retina remained on dry ice to prevent metabolite degradation while the metabolite extraction was conducted. Tissues were transferred to 0.5mL Soft Tissue Lysing Kit Precellys tubes containing beads. Then, 84 µL of chilled 1:1 MeOH/H2O were added to Precellys tube. Pre-extraction internal standards were added to the tubes: 5µl of 1mg/ml Caffeine 13C6, 5µl of 1mg/ml D-Glucose 13C6, 5µl of 1mg/ml Oleic Acid 13C5, and 1µl of 5mg/mL Isoleucine 13C6 to each sample. Tissues were homogenized using Precellys 24 Touch. Cycle parameters: 2 cycles: 30 seconds homogenization at 4500 rpm, 10 seconds rest. Homogenate was transferred to a microcentrifuge tube and centrifuged at 18000xrcf for 20 min at 4°C. Then, collect supernatant and transfer pellet to Precellys Lysing Kit tube. Add 84uL of 8:1:1 Acetonitrile/Methanol/Acetone to pellet and add the rest of the pre-extraction internal standards: 5µl of 1mg/ml Caffeine 13C6, 5µl of 1mg/ml D-Glucose 13C6, 5µl of 1mg/ml Oleic Acid 13C5, 1µl of 5mg/mL Isoleucine 13C6. Final pre-extraction internal standards concentrations are 50μg/mL. Homogenization cycles were repeating using Precellys 24 Touch. Centrifuge as before and add second supernatant to first round of collected supernatant. Centrifuge at 1800xrcf for 20 min once more to remove any remaining tissue debris. Collect supernatant and dry supernatant in Speedvac. Two extraction blanks were prepared in the same manner as the biological samples. Dried samples were reconstituted immediately in 0.1% formic acid in 44.75µL of HPLC-MS grade water. Post-extraction internal standards were added: 25 µl of 5mg/ml Phenylalanine 13C6, 2.5 µl of .5mg/ml Uracil 13C 15N2, 1.25 µl of 1mg/ml Arginine 13C6, 1.25 µl of 1mg/ml Serine 13C3 to each sample.

Sampleprep ID:

SP003405

Sampleprep Summary:

Retina remained on dry ice to prevent metabolite degradation while the metabolite extraction was conducted. Tissues were transferred to 0.5mL Soft Tissue Lysing Kit Precellys tubes containing beads. Then, 84 µL of chilled 1:1 MeOH/H2O were added to Precellys tube. Pre-extraction internal standards were added to the tubes: 5µl of 1mg/ml Caffeine 13C6, 5µl of 1mg/ml D-Glucose 13C6, 5µl of 1mg/ml Oleic Acid 13C5, and 1µl of 5mg/mL Isoleucine 13C6 to each sample. Tissues were homogenized using Precellys 24 Touch. Cycle parameters: 2 cycles: 30 seconds homogenization at 4500 rpm, 10 seconds rest. Homogenate was transferred to a microcentrifuge tube and centrifuged at 18000xrcf for 20 min at 4°C. Then, collect supernatant and transfer pellet to Precellys Lysing Kit tube. Add 84uL of 8:1:1 Acetonitrile/Methanol/Acetone to pellet and add the rest of the pre-extraction internal standards: 5µl of 1mg/ml Caffeine 13C6, 5µl of 1mg/ml D-Glucose 13C6, 5µl of 1mg/ml Oleic Acid 13C5, 1µl of 5mg/mL Isoleucine 13C6. Final pre-extraction internal standards concentrations are 50μg/mL. Homogenization cycles were repeating using Precellys 24 Touch. Centrifuge as before and add second supernatant to first round of collected supernatant. Centrifuge at 1800xrcf for 20 min once more to remove any remaining tissue debris. Collect supernatant and dry supernatant in Speedvac. Two extraction blanks were prepared in the same manner as the biological samples. Dried samples were reconstituted immediately in 0.1% formic acid in 44.75µL of HPLC-MS grade water. Post-extraction internal standards were added: 25 µl of 5mg/ml Phenylalanine 13C6, 2.5 µl of .5mg/ml Uracil 13C 15N2, 1.25 µl of 1mg/ml Arginine 13C6, 1.25 µl of 1mg/ml Serine 13C3 to each sample.

Combined analysis:

Analysis ID	AN005369	AN005370
Analysis type	MS	MS
Chromatography type	HILIC	HILIC
Chromatography system	Thermo Vanquish	Thermo Vanquish
Column	Thermo Accucore Amide HILIC (150 x 2.1mm, 2.6um)	Thermo Accucore Amide HILIC (150 x 2.1mm, 2.6um)
MS Type	ESI	ESI
MS instrument type	Orbitrap	Orbitrap
MS instrument name	Thermo Q Exactive Orbitrap	Thermo Q Exactive Orbitrap
Ion Mode	POSITIVE	NEGATIVE
Units	Peak area	Peak area

Chromatography:

Chromatography ID:	CH004068
Chromatography Summary:	Positive ion mode
Instrument Name:	Thermo Vanquish
Column Name:	Thermo Accucore Amide HILIC (150 x 2.1mm, 2.6um)
Column Temperature:	35 C
Flow Gradient:	The gradient began at 1.0% B for 1 min, then shifted to 95.0% B for 9 minutes, then stayed at 95.0% B for 1 min before ramping down quickly to 1.0% B and held for 5 minutes.
Flow Rate:	0.5 ml/min
Solvent A:	95% acetonitrile/5% water; 10mM Ammonium Formate; 0.1% formic acid
Solvent B:	50% acetonitrile/50% water; 10mM Ammonium Formate; 0.1% formic acid
Chromatography Type:	HILIC

Chromatography ID:	CH004069
Chromatography Summary:	Negative ion mode
Instrument Name:	Thermo Vanquish
Column Name:	Thermo Accucore Amide HILIC (150 x 2.1mm, 2.6um)
Column Temperature:	35 C
Flow Gradient:	The gradient began at 1.0% B for 1 min, then shifted to 95.0% B for 9 minutes, then stayed at 95.0% B for 1 min before ramping down quickly to 1.0% B and held for 5 minutes.
Flow Rate:	0.5 ml/min
Solvent A:	95% acetonitrile/5% water; 10mM Ammonium Acetate; 0.1% acetic acid
Solvent B:	50% acetonitrile/50% water; 10mM Ammonium Acetate; 0.1% acetic acid
Chromatography Type:	HILIC

MS:

MS ID:	MS005098
Analysis ID:	AN005369
Instrument Name:	Thermo Q Exactive Orbitrap
Instrument Type:	Orbitrap
MS Type:	ESI
MS Comments:	The samples were run using a Q ExactiveTM mass spectrometer coupled to a heated electrospray ionization (HESI) source. The spray voltage was set to 3.50 kV, capillary temperature to 350°C, sheath gas to 55, aux gas to 14, sweep gas to 4, and S-Lens RF Level to 30.0. The mass range was set to 67 – 1000 m/z, resolution 140,000 for full scan and 35,000 for ddMS2. AGC target was set to 1e6 for full scan and 2e5 for ddMS2. The max injection time (IT) was 100 seconds for full scan mode and 50 seconds for ddMS2. The number of microscans was 2, and normalized collision energy (NCE) was set to 20, 35, and 50. Samples were run in both positive and negative ion mode separately. The parameters for negative mode were the same except the spray voltage, which was set to 2.50 kV and capillary temperature to 380°C. Metabolites were identified from their Thermo.RAW scans using Compound DiscovererTM 3.3 software. Extraction blanks were used to determine and correct for reagent effects, allow for the creation of exclusions lists, mark background components, and filters the background components from the results table in Compound DiscovererTM 3.3. Pooled QCs were used for initial compound normalization and identification. All non-identified compounds were removed.
Ion Mode:	POSITIVE

MS ID:	MS005099
Analysis ID:	AN005370
Instrument Name:	Thermo Q Exactive Orbitrap
Instrument Type:	Orbitrap
MS Type:	ESI
MS Comments:	The samples were run using a Q ExactiveTM mass spectrometer coupled to a heated electrospray ionization (HESI) source. The spray voltage was set to 3.50 kV, capillary temperature to 350°C, sheath gas to 55, aux gas to 14, sweep gas to 4, and S-Lens RF Level to 30.0. The mass range was set to 67 – 1000 m/z, resolution 140,000 for full scan and 35,000 for ddMS2. AGC target was set to 1e6 for full scan and 2e5 for ddMS2. The max injection time (IT) was 100 seconds for full scan mode and 50 seconds for ddMS2. The number of microscans was 2, and normalized collision energy (NCE) was set to 20, 35, and 50. Samples were run in both positive and negative ion mode separately. The parameters for negative mode were the same except the spray voltage, which was set to 2.50 kV and capillary temperature to 380°C. Metabolites were identified from their Thermo.RAW scans using Compound DiscovererTM 3.3 software. Extraction blanks were used to determine and correct for reagent effects, allow for the creation of exclusions lists, mark background components, and filters the background components from the results table in Compound DiscovererTM 3.3. Pooled QCs were used for initial compound normalization and identification. All non-identified compounds were removed.
Ion Mode:	NEGATIVE