A subscription to JoVE is required to view this content. Sign in or start your free trial.

In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

This protocol describes procedures to isolate high-quality nuclei from frozen non-human primate pancreatic islets for use in single-nucleus simultaneous RNA sequencing and ATAC sequencing while preserving the bulk cytosolic fraction for metabolomic analyses from the same samples.

Abstract

One challenge in studies using tissue collected from multiple cohorts is avoiding batch effects when preparing for large-scale multi-omic experiments, such as combined single-cell RNA sequencing and metabolomics. The method in the current study utilizes flash-frozen pancreatic islets from fetal non-human primates collected over a span of two years for input into single-nucleus RNA sequencing and ATAC sequencing assays. The cytosolic fraction generated during nuclear extraction was retained for downstream capillary electrophoresis-mass spectrometry and subsequent metabolite quantification. This method allows for bulk analysis of metabolites that contribute to the changing transcriptomic and epigenomic landscapes within experimental conditions. It is applicable to many tissue types and maximizes the amount of information that can be extracted from samples that are not readily available. As the contribution of metabolism to the establishment of cellular identity via epigenetic modifications becomes more appreciated, techniques that allow for identifying the contribution of metabolites in specific cell types are timely and necessary.

Introduction

The pancreatic islets of Langerhans are critical for the management of glucose tolerance throughout the lifespan. Failure to properly tune blood glucose levels via the glucose-lowering hormone, insulin, or the glucose-raising hormone, glucagon results in Diabetes Mellitus1. Modifiable risk factors to minimize diabetes risk include exercise and diet. In addition, it is becoming clear that maternal diet during pregnancy also has an effect on offspring susceptibility to diabetes in adulthood2,3. Thus, methods are needed to analyze the effects of maternal diet and other exposures, such as medications used during pregnancy, on the insulin-producing beta cells in model organisms during development. For example, islets from fetal non-human primate (NHP) offspring can be evaluated for the effects of developmental exposures. Similar to humans, NHPs typically have singleton births and vary in their physiological response to Western-style diet feeding4. While the gestation and fetal development of NHPs shares many similarities with humans, making them a highly relevant species for metabolic programming studies, challenges to performing comparative bioinformatic assays on NHP offspring include a restricted mating season and intermittent sample collection. Therefore, approaches that allow for long-term storage prior to sample processing and analysis are ideal. This protocol describes the preparation of samples for single nucleus RNA-sequencing, ATAC-sequencing, and bulk cytoplasmic metabolomics.

Studies by others in the islet biology field have demonstrated overlap in the genetic signatures observed in samples prepared via single-cell RNA Sequencing and single-nucleus RNA sequencing5,6. Both methods allow for the identification of transcripts that contribute to distinguishing features amongst various cell types within the islet population. Through the use of gentle detergents on flash-frozen tissue, intact nuclei can simultaneously be used for ATAC sequencing, which allows for the determination of accessible chromatin regions. Combining single-nucleus RNA-sequencing with ATAC-sequencing allows for better characterization of gene regulatory networks7.

The preparation of samples for metabolomics has traditionally been limited by the need for a high sample volume input for liquid chromatography. In addition, careful consideration must be given to the buffers used during sample preparation to avoid false NMR peaks in mass spectrometric data. Given the low number of samples that are challenging and costly to acquire in primate studies, allocation of islets from different offspring toward transcriptomic versus metabolomic experiments can be difficult. Thus, this protocol makes use of the normally discarded cytosolic fraction generated during cellular fractionation for single-nucleus experiments. This method allows for the simultaneous characterization of transcripts and open chromatin regions that define cellular subsets in fetal islets while quantitatively measuring the metabolites produced within islets (Figure 1). This protocol is adapted from a demonstrated protocol published by 10x genomics for the isolation of nuclei from flash-frozen embryonic mouse brain tissue (version CG000366 Rev D8)7.

Protocol

Islet retrieval was conducted in accordance with the guidelines of the Institutional Animal Care and Use Committee (IACUC) of the Oregon National Primate Research Center (ONPRC) and Oregon Health and Science University and was approved by the ONPRC IACUC. The ONPRC abides by the Animal Welfare Act and Regulations enforced by the United States Department of Agriculture (USDA) and the Public Health Service Policy on Humane Care and Use of Laboratory. The protocol herein was applied to islets from fetal Rhesus macaques that were necropsied on gestational day 145 (Rhesus macaque gestation is typically 173-175 days). The details of the reagents and the equipment used for this study are listed in the Table of Materials.

1. Islet isolation

  1. Excise fetal pancreata from surrounding tissues9 and place it in ice-cold phosphate-buffered saline.
  2. Remove the pancreas from PBS and inflate it with collagenase P (0.6 mg/mL) via cannulation of the pancreatic duct using a 33 G rodent brain cannula injector.
  3. Divide the pancreas into six sections with sterile surgical scissors and digest for 27-30 min at 37 Β°C in collagenase solution.
  4. Prepare RT media by combining 10% FBS and 100 U/mL penicillin/streptomycin into RPMI 1640.
  5. Pour off collagenase and add 10 mL of RT media.
  6. Gently shake for 1 min to disrupt the remaining connective tissue.
  7. Remove undigested material by straining through a 500 Β΅m filter.
  8. Wash the islets twice with 50 mL of RT media.
  9. Incubate the islets in bovine DNase I (0.8 U/mL) in a 37 Β°C water bath for 10 min.
  10. Culture the islets overnight in RT media with bovine DNase I (0.4 U/mL) at 37 Β°C with 5% CO2.
  11. Ship islets in specialized packaging at ambient temperature with temperature control gel packs.

2. Sample banking for long-term storage

  1. Assess islets for size using a scaled reticle and note the degree of acinar and ductal tissue in preparation.
  2. Handpick islets with an automated pipette into a 60 mm dish containing 5 mL of 2.8 mM glucose DMEM.
    NOTE: It is imperative to minimize the amount of acinar tissue and ductal tissue that will be stored in the final islet preparation. Details of ideal islets for use are reported in a previous protocol9.
  3. Pick islets into a 1.5 mL tube and spin at ~300 x g for 5 min at 4 Β°C.
  4. Resuspended the islets in calcium and magnesium-free 1x PBS.
  5. Spin for 5 min at ~300 x g at 4 Β°C. Discard the supernatant.
  6. Repeat steps 2.3-2.5 twice more.
  7. Flash freeze the islets in a 1.5 mL tube for 10 s in liquid nitrogen.
  8. Store the pellet at -80 Β°C until the day of nuclear isolation.

3. Cellular fractionation for isolation of nuclei and cytoplasmic fraction

  1. Preparation of buffers for nuclei extraction (Table 1).
    1. Ensure that the bench, pipettes, and reagents are RNase-free.
    2. Prepare the wash, concentrated lysis, lysis dilution, and diluted nuclei buffers according to Table 1.
    3. Prepare 0.1x lysis buffer in a 5 mL tube using the lysis dilution buffer to dilute the concentrated lysis buffer.
  2. Tissue homogenization
    1. Remove the samples from -80 Β°C freezer and immediately place them on ice.
    2. Add 500 Β΅L of 0.1x lysis buffer to the tissue pellets and incubate for 3 min on ice.
    3. Using a disposable RNase-free pellet pestle, gently homogenize the tissue 15 times on ice.
    4. Incubate the samples on ice for 10 min.
    5. Add 500 Β΅L of wash buffer to the homogenate and gently pipette on ice.
    6. Prime a 30 Β΅m pre-separation filter by adding 300 mL of wash buffer to the filter over a 5 mL tube.
    7. Filter the 1 mL cellular homogenate using the 30 Β΅M pre-separation filter into the 5 mL tube.
    8. Spin the filtered homogenate at 500 x g for 5 min in a swinging bucket centrifuge at 4 Β°C.
  3. Collection and storage of supernatant for metabolomics
    1. Remove 1 mL of the supernatant from step 3.2.8 with a pipette and add to a 1.5 mL cryovial on ice.
    2. Immediately freeze the supernatant at -80 Β°C. This supernatant will be used for metabolomics.
  4. Preparation of nuclei for single nucleus RNA- and ATAC-sequencing
    1. Gently resuspend the nuclei pellet by adding 1 mL of wash buffer to the pellet dropwise. Slowly pipette 5 times.
    2. Spin the washed pellet at 1000 x g for 5 min in a swinging bucket centrifuge at 4 Β°C.
    3. Repeat steps 3.4.1 and 3.4.2 once more.
    4. After the final wash, resuspend the nuclei in 1 mL of wash buffer. Keep nuclear preparation on ice.
    5. Aspirate 10 Β΅L of nuclei suspension with a pipette and mix with 10 Β΅L of 0.4% Trypan blue by gently pipetting.
    6. Add 10 Β΅L of the nuclei and Trypan blue mixture to an automated cell counter slide with a pipette and place it in the instrument.
    7. Determine nuclei concentration in nuclei/Β΅L.
      NOTE: Unlike cellular preparations for single-cell RNA sequencing, automated cell counters will detect nuclei as dead cells. No more than 95% of this preparation should be live on automated cell counters. If more than 5% of the nuclear population is live, the nuclei suspension can be filtered an additional time through the 30 Β΅m pre-separation filter and spun for 5 min at 1000 x g at 4 Β°C. Nuclei concentration can then be recalculated as outlined in step 3.4.6.
    8. Based on the desired targeted nuclei recovery, resuspend nuclei to the necessary concentration using 1x nuclei buffer and proceed to single nucleus RNA and ATAC sequencing library preparation10.

4. Preparation of cytosolic fraction for capillary electrophoresis- mass spectrometry (CE-MS)

  1. Combine 80 Β΅L of cytosolic fraction collected in step 3.3.1 with 20 Β΅L of nanopure water containing internalized standards.
  2. Proceed with CE-MS and analysis as previously described11,12,13.

Results

The quality of the sequencing outputs is highly dependent on the quality of the nuclear input. Nuclear blebbing and damage to the outer nuclear membrane will result in ambient RNA and DNA contamination in the analysis, which will introduce noise in the data. A pure nuclear extract will have minimal evidence of nuclei encapsulated with cytoplasmic components (Figure 2A) or overdigestion, evidenced by bursting nuclei (Figure 2B). An ideal nuclear input will contai...

Discussion

Historically, the methods of nuclear isolation for single nucleus RNA- and ATAC-sequencing have utilized buffers containing detergents that are incompatible with liquid chromatography-mass spectrometry (LC-MS), a common technique used for metabolite quantification16,17. The current protocol allows for the combination of transcriptomic and metabolomic techniques from the same sample preparation by using a gentle detergent for cellular fractionation, and following ...

Disclosures

The authors declare no conflicts of interest.

Acknowledgements

The authors would like to thank the entire team at the Oregon Health Sciences University for taking care of the non-human primate colony and for tissue acquisition. Additionally, Vanderbilt Technologies for Advanced Genomics provided technical expertise and experimental design advice. DTC was supported by an F31 pre-doctoral fellowship from the NIH/NIDK (1F31DK135164). PK was supported by the NIH/NIDDK (1R01DK128187). MG was supported by a VA Merit award (I01 BX005399), the NIH/NIDDK (1R01DK135032, 1R01DK128187), and the JDRF (2-SRA-2024-1455-S-B). Work at the Oregon National Primate Research Center (ONPRC) was supported by P51OD011092 for operational support of the Center.

Materials

NameCompanyCatalog NumberComments
33 G rat brain cannula injectorProtech International8IC315IS5SPCFor duct cannulation and pancreas inflation
Penicillin/StreptomycinFisher15-140-122For RT media
FBSMillipore/SigmaF4135-500MLFor RT media
RPMI 1640Thermo Fisher Scientific11-875-135For RT media
Collagenase PSigma Aldrich11213865001For digestion of pancreas
Bovine Dnase ISigma Aldrich11284932001For RT media and isolation
DextroseFisherD16-1Final concentration will be 2.8 mM
Calcium ChlorideFisherC4901-500GFinal concentration will be 0.5 mM
HEPESGibco15630-080Final concentration will be 10 mM
Bovine Serum Albumin (BSA) Fraction 5Research Products InternationalA30075100Final concentration will be 0.5 mg/mL
Dulbecco's Modified Eagle MediumGibco11966025For handpicking islets
20x Nuclei Buffer10X Genomics2000153/2000207
Digitonin (5%)Thermo Fisher ScientificBN2006Digitonin may need to be warmed to 65 Β°C to dissolve white precipitate
MACS SmartStrainers (30 Β΅M)Miltenyi Biotec130-098-458
MACS BSA Stock Solution (10%)Miltenyi Biotec130-091-376
IGEPAL CA-630Sigma Aldrichi8896Prepare a 10% stock using MilliQ water
Trizma Hydrochloride Solution, pH 7.5Sigma AldrichT2319-1L
Sodium Chloride Solution, 5 MSigma AldrichS6546-1L
Magnesium Chloride Solution, 1 MSigma AldrichM1028-100mL
Sigma Protector Rnase inhibitorSigma Aldrich3335402001
DTTResearch Products InternationalD11000-5.0
Rnase-Free Disposable Pellet PestlesFisher Scientific12-141-368
Tween 20Fisher BioreagentsBP337-500Prepare a 20% stock using MilliQ water
Nuclease-Free WaterPromegaPR-P1193
DNA LoBind Tubes (5 mL)Eppendorf30108310
Cryovials (1.5 mL)VWR20170-225
Posi-Click Tubes (0.6 mL)DenvilleC-2177
Trypan Blue (0.4%)Thermo Fisher ScientificT-10282
Dual-Chamber Cell Counting SlidesBio-Rad1450011
MiiliQ Ultrapure Water SystemMillipore/Sigma7003/05/10/15
5 kDa cut-off filterHMT Metabolome Technologies
Internal StandardsHMT Metabolome Technologies
P10, P20, P200, and P1000 PipettesEppendorf2231000602
Pipette Tips, 10 Β΅LVWR76322-528
Pipette Tips, 1000 Β΅LThermo Fisher Scientific21-236-2A
Pipette Tips, 20 Β΅LGenesee Scientific23-404
Pipette Tips, 200 Β΅LUSA Scientific1120-8810
Phase Contrast MicroscopeOlympusBX41-PH-B
Countess II Automated Cell CounterThermo Fisher ScientificAMQAX1000
DPBS (1x)Β Gibco14190-144
Allegra X-30R CentrifugeBeckman-CoulterB06315
RNase-ZAPSigma AldrichR2020

References

  1. Christensen, A. A., Gannon, M. The beta cell in type 2 diabetes. Curr Diab Rep. 19 (9), 81 (2019).
  2. Elsakr, J. M., Gannon, M. Developmental programming of the pancreatic islet by. Trends Dev Biol. 10, 79-95 (2017).
  3. Salzberg, L. Risk factors and lifestyle interventions. Prim Care. 49 (2), 201-212 (2022).
  4. Pound, L. D., Kievit, P., Grove, K. L. The non-human primate as a model for type 2 diabetes. Curr Opin Endocrinol Diabetes Obes. 21 (2), 89-94 (2014).
  5. Kang, R. B., et al. Single-nucleus RNA sequencing of human pancreatic islets identifies novel gene sets and distinguishes Ξ²-cell subpopulations with dynamic transcriptome profiles. Genome Med. 15 (1), 30 (2023).
  6. Basile, G., et al. Using single-nucleus RNA-sequencing to interrogate transcriptomic profiles of archived human pancreatic islets. Genome Med. 13 (1), 128 (2021).
  7. CabΓ©, C. M., et al. High-quality brain and bone marrow nuclei preparation for single nuclei multiome assays. J Vis Exp. (202), e65715 (2023).
  8. . Nuclei from embryonic mouse brain for single cell multiome ATAC + gex sequencing Available from: https://www.10xgenomics.com (2022)
  9. Elsakr, J. M., Deeter, C., Ricciardi, V., Gannon, M. Analysis of non-human primate pancreatic islet oxygen consumption. J Vis Exp. (154), e60696 (2019).
  10. . Chromium next gem single cell multiome ATAC + gene expression reagent kits user guide Available from: https://www.10xgenomics.com (2022)
  11. Maruyama, A., et al. Extraction of aqueous metabolites from cultured adherent cells for metabolomic analysis by capillary electrophoresis-mass spectrometry. J Vis Exp. (148), e59551 (2019).
  12. Ooga, T., et al. Metabolomic anatomy of an animal model revealing homeostatic imbalances in dyslipidaemia. Mol Biosyst. 7 (4), 1217-1223 (2011).
  13. Ohashi, Y., et al. Depiction of metabolome changes in histidine-starved Escherichia coli by CE-TOFMS. Mol Biosyst. 4 (2), 135-147 (2008).
  14. Chiou, J., et al. Single-cell chromatin accessibility identifies pancreatic islet cell type– and state-specific regulatory programs of diabetes risk. Nat Genetics. 53 (4), 455-466 (2021).
  15. Pang, Z., et al. Metaboanalyst 6.0: Towards a unified platform for metabolomics data processing, analysis and interpretation. Nucleic Acids Res. , 253 (2024).
  16. Willency, J. A., Lin, Y., Pirro, V. Targeted metabolomics in human and animal biofluids and tissues using liquid chromatography coupled with tandem mass spectrometry. STAR Protoc. 5 (1), 102884 (2024).
  17. Behnke, J. -. S., Urner, L. H. Emergence of mass spectrometry detergents for membrane proteomics. Anal Bioanal Chem. 415 (18), 3897-3909 (2023).
  18. Ouimet, C. M., D'amico, C. I., Kennedy, R. T. Advances in capillary electrophoresis and the implications for drug discovery. Expert Opin Drug Discov. 12 (2), 213-224 (2017).
  19. Alexandrov, T. Spatial metabolomics and imaging mass spectrometry in the age of artificial intelligence. Annu Rev Biomed Data Sci. 3, 61-87 (2020).
  20. Ewald, J. D., et al. Web-based multi-omics integration using the analyst software suite. Nat Protoc. 19, 1467-1497 (2024).

Reprints and Permissions

Request permission to reuse the text or figures of this JoVE article

Request Permission

Explore More Articles

Developmental Biology

This article has been published

Video Coming Soon

JoVE Logo

Privacy

Terms of Use

Policies

Contact Us

Recommend to library

JoVE NEWSLETTERS

Research

Education

Authors

Librarians

ABOUT JoVE

Copyright Β© 2025 MyJoVE Corporation. All rights reserved