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W tym Artykule

  • Podsumowanie
  • Streszczenie
  • Wprowadzenie
  • Protokół
  • Wyniki
  • Dyskusje
  • Ujawnienia
  • Podziękowania
  • Materiały
  • Odniesienia
  • Przedruki i uprawnienia

Podsumowanie

We present protocols for three different methods for the homogenization of four different muscle groups of rat skeletal muscle tissue to measure and compare the levels of nitrate and nitrite. Furthermore, we compare different sample weights to investigate whether tissue sample size affects the results of homogenization.

Streszczenie

Nitrate ions (NO3-) were once thought to be inert end products of nitric oxide (NO) metabolism. However, previous studies demonstrated that nitrate ions can be converted back to NO in mammals through a two-step reduction mechanism: nitrate being reduced to nitrite (NO2-) mostly by oral commensal bacteria, then nitrite being reduced to NO by several mechanisms including via heme- or molybdenum-containing proteins. This reductive nitrate pathway contributes to enhancing NO-mediated signaling pathways, particularly in the cardiovascular system and during muscular exercise. The levels of nitrate in the body before such utilization are determined by two different sources: endogenous NO oxidation and dietary nitrate intake, principally from plants. To elucidate the complex NO cycle in physiological circumstances, we have examined further the dynamics of its metabolites, nitrate and nitrite ions, which are relatively stable compared to NO. In previous studies skeletal muscle was identified as a major storage organ for nitrate ions in mammals, as well as a direct source of NO during exercise. Therefore, establishing a reliable methodology to measure nitrate and nitrite levels in skeletal muscle is important and should be helpful in extending its application to other tissue samples. This paper explains in detail the preparation of skeletal muscle samples, using three different homogenization methods, for nitrate and nitrite measurements and discusses important issues related to homogenization processes, including the size of the samples. Nitrate and nitrite concentrations have also been compared across four different muscle groups.

Wprowadzenie

Nitric oxide (NO), a small gaseous signaling molecule, plays a critical role in physiological and pathophysiological processes1. NO can be produced from L-arginine by endogenous enzymes of the nitric oxide synthase (NOS) family before undergoing rapid oxidation to nitrate (NO3-) and, possibly, nitrite (NO2-) in blood and tissues2,3. Recently, these anions have been shown to be reduced back to NO in mammalian systems4. Nitrate is converted to nitrite, mainly by commensal bacterial nitrate reductases in the oral cavity acting on ions secreted by the salivary glands and directly ingested 5, and to some extent, by mammalian enzymes such as xanthine oxidoreductase6,7. Nitrite can be further reduced to NO by several mechanisms including deoxyhemoglobin8, deoxymyoglobin9, molybdenum-containing enzymes10, and non-enzymatic reduction in the presence of protons11,12.

This nitrate-nitrite-NO pathway is enhanced under hypoxic conditions wherein NOS activity is diminished because NOS requires oxygen for NO generation4. Many recent studies have reported beneficial effects of dietary nitrate on blood pressure regulation and exercise performance, suggesting that nitrate reduction pathways contribute to the augmentation of NO signaling13,14,15. Previous studies have shown that some skeletal muscles are likely the major nitrate storage places in the body16. Compared to blood or other internal organs such as liver, skeletal muscle (gluteus maximus) contains significantly higher levels of nitrate and has a substantial mass in the mammalian body. Treadmill exercise was shown to enhance nitrate reduction to nitrite and to NO in gluteus in a rat model7. These results imply that some skeletal muscles could be important sources for NO through nitrate reduction pathways in physiological situations. More recent studies suggest that these findings, including changes in muscle nitrate levels during exercise, also occurs in humans17.

Two of the current authors had previously established a method to measure nitrate and nitrite levels in blood and other liquid samples18. However, when the levels of these anions in tissue homogenates were initially analyzed, detailed protocols were not available. To understand the nitrate-nitrite-NO dynamics in several different organs, our goal was to develop an accurate and efficient method to measure nitrate and nitrite levels in mammalian tissues including skeletal muscle. In earlier studies, rodent tissues were used to develop reliable homogenization processes and then analyze nitrate and nitrite contents in those homogenates7,16,19. The usage of this homogenization method was extended to human skeletal muscle biopsy samples, whereby the values were confirmed, and importantly, the values observed for muscle compared to blood/plasma were in similar ranges and ratios to those observed in rodents17. In recent years, other groups also started measuring nitrate and nitrite levels in skeletal muscle homogenates, reporting comparable values to the ones reported by our group20,21.

The aim of this protocol paper is to describe in detail the preparation of skeletal muscle homogenates using three different homogenization methods for subsequent measurement of nitrate and nitrite levels. Additionally, the effects of tissue weight used for homogenization on values of nitrate and nitrite in skeletal muscle samples were examined. We believe that these methods can be easily applied to other types of mammalian tissues. Recently, especially in the field of exercise physiology, attention had been paid to the possible differences in nitrate/nitrite/NO physiology according to muscle groups. We also report the amounts of nitrate and nitrite in four different rodent muscles and find a nonuniform distribution of both ions among these different muscles; an observation which requires further study.

Protokół

Animal protocol was approved by NIDDK Animal Care and Use Committee (ASP K049-MMB-20). Animals were handled and treated according the current Guide for the Care and Use of Laboratory Animals freely available on AAALAC website.

1. Rat skeletal muscle collection

  1. While a rat is under deep anesthesia (5% isoflurane, confirmed by absent reaction to tail/leg pinch), start perfusion with saline containing heparin by placing a 19 G needle into an apex of the left ventricle and making a nick on the right atrium. Allow saline with heparin to perfuse through the internal organs until at least 1.5 liter/kg have flowed through the tissue. At this point, animals are dead from exsanguination and carcasses are ready to be processed for sample collection.
    NOTE: Achieving good perfusion is critical, especially for accurate measurements of nitrite, because nitrite is oxidized into nitrate by any remaining hemoglobin.
  2. Identify target muscle tissues and excise them from the hind legs22 using clean surgical instruments. Remove as much fat and connective tissues from the muscle tissues as possible.
  3. Place the desired amount of muscle into a microcentrifuge tube and then place on dry ice. Store the tubes filled with tissue in the -80 °C freezer.
    ​NOTE: In case of human biopsy samples, thoroughly blot them immediately upon collection with clean gauze to remove excess blood.

2. Preparation for homogenization

  1. Preparation of nitrite-preserving solution (stop solution)
    1. Prepare a clear yellow solution containing 890 mM potassium ferricyanide (K3Fe(CN)6) and 118 mM NEM (N-ethylmaleimide) in distilled water, ensuring no crystals. Add non-ionic surfactant (detergent) in a 1:9 ratio (v/v, Table of Materials), and mix gently to avoid foaming.
    2. Dilute the stop solution in a 1:9 ratio with distilled water. Place the diluted stop solution (1:5 ratio of muscle tissue to diluted stop solution) in the homogenization tube.
      NOTE: Twenty milligrams of tissue will require 100 μL of stop solution, and 200 mg of tissue will require 1000 μL of stop solution in the tube. Presence of detergent in added solution is critical for disruption of cell membranes. Any non-ionic detergent can be used, but care must be taken to verify that it does not interfere with chemiluminescence method.
  2. Tissue preparation
    1. Take the tissue out of the -80 °C freezer and slowly thaw in ice. Remove the remaining fat and connective tissue from the skeletal muscle. Cut off pieces of skeletal muscle and blot on gauze to dry.
    2. Weigh out the amount of tissue (20, 50, and 200 mg). Place the pre-weighed skeletal muscle in the stop-solution in the homogenization tubes or place the pre-weighed tissue in a clean microcentrifuge tube for later use.

3. Homogenization

  1. Rotary homogenizer (Figure 1)
    1. Place the M-type tube containing the pre-weighed skeletal muscle and pre-measured stop solution into the machine. Homogenize each sample twice (setting on the most destructive homogenization cycle) and place the tube on ice immediately after each homogenization for 5 min to cool down.
    2. Centrifuge briefly at 2,000 × g and 4 °C for 5 min. Place the full tube back on ice and add the appropriate volume of methanol (≥ 99.9 %, 10x of tissue weight). Vortex thoroughly for 15 s.
      ​NOTE: For 20 mg of tissue, use 200 μL of methanol. Methanol is used to precipitate proteins from tissue homogenate and does not interfere with chemiluminescence method. If other protein precipitation method is used, test its compatibility with chemiluminescence.
    3. Homogenize once more and incubate on ice for 30 min. Centrifuge the samples for 35 min at 4 °C and 3,500 × g. Aspirate the supernatant, and measure nitrite/nitrate levels, or store at -80 °C for later use.
  2. Bead homogenizer (Figure 2)
    1. Place the skeletal muscle tissue in a bead-containing tube (1:5 ratio for tissue:diluted stop solution) and homogenize twice for 45 s at the highest speedavailable on the instrument used. Place the tube on ice immediately after each homogenization for 5 min to cool down.
    2. Briefly centrifuge using a small desktop centrifuge (2,000 x g) for 5 sec. Place the tube back on ice and add an appropriate volume of methanol (purity ≥ 99.9 %, 10x of tissue weight). Vortex thoroughly for 15 s.
      NOTE 1: For 20 mg of tissue, use 200 μL of methanol.
      NOTE 2: Methanol is used to precipitate proteins from tissue homogenate and does not interfere with chemiluminescence method. If other protein precipitation method is used, test its compatibility with chemiluminescence.
    3. Homogenize once more for 45 s at the highest speed available on the instrument used. Incubate on ice for 30 min. Centrifuge at 17,000 x g, 4 °C, 30 min. Aspirate the supernatant, and measure nitrite/nitrate levels, or store at -80 °C for later use.
  3. Pulverizer (Figure 3)
    1. Prepare tubes containing diluted stop solution (5x of tissue weight) and weigh them. Record the weight (tube + stop solution).
    2. Place the liquid nitrogen pulverizer tool on dry ice and wait for approximately 30 min for it to reach the desired temperature.
    3. Using tweezers chilled in liquid nitrogen, transfer one sample (tissue weight measured already) to the pulverizer. Add a small spoonful of liquid nitrogen to ensure the tissue is at liquid nitrogen temperature.
    4. After 95% of the liquid nitrogen has vaporized, place the crushing tool on top of the tissue, and press firmly. You should feel the sample crush. Using the mallet, strike the crushing tool 3-5x.
    5. Check the sample for any remaining chunks using a spoon cooled in liquid nitrogen. After cooling in liquid nitrogen, use a piece of tissue paper to wipe away any frozen water before touching the tissue. If a chunk is present, move it into the center, and then strike 5-6 more times with the mallet.
    6. When the whole sample has been pulverized, use the liquid nitrogen-cooled spoon to directly transfer the crushed tissue into the pre-weighed tube containing the diluted stop solution (step 3.3.1). Be sure to perform this step quickly as when the crushed skeletal muscle heats up, it gets sticky and difficult to transfer.
    7. Vortex for 15 s. Check that no tissue is stuck at the top of the tube by opening the tube. If there is, try to dislodge it and then vortex again.
    8. Centrifuge the sample for 2-3 s using a small desktop centrifuge. Weigh the tube again. Calculate the tissue weight by deducting the original tube weight (step 3.3.1) from this new weight. Place the tube on ice.
      NOTE: The exact weights will help determine the exact tissue weight and how much tissue was lost during pulverization.
    9. Once all samples have been processed up to step 3.3.8, add an appropriate volume of methanol (≥ 99.9 %, 10x of tissue weight). Vortex thoroughly for 15 s, and incubate on ice for 30 min.
      NOTE: For 20 mg of tissue, use 200 μL of methanol. Methanol is used to precipitate proteins from tissue homogenate and does not interfere with chemiluminescence method. If other protein precipitation method is used, test its compatibility with chemiluminescence.
    10. Centrifuge at 17,000 × g, 4 °C, 30 min. Aspirate the supernatant and measure nitrite/nitrate levels, or store at -80 °C for later use.

4. Nitrite/nitrate measurement with nitric oxide analyzer (NOA)

  1. Prepare all samples by either of three different homogenization methods described above and inject them into an NOA for nitrate and nitrite measurement.
    NOTE: Detailed protocols for NOA use were published previously19.

Wyniki

To obtain representative results, skeletal muscle tissues from 8 Wistar rats (males and females, weight 250 ± 50 g) were used. Rat skeletal muscle homogenates (50 mg of gluteus maximus muscle for each method) were prepared by three different homogenization tools (rotary homogenizer, bead homogenizer, and pulverizer). The nitrate and nitrite contents of these homogenates were then determined using a nitric oxide analyzer (NOA) (Figure 4). Nitrate levels (Figure 4A

Dyskusje

To monitor changes in the NO metabolites, nitrate and nitrite, as a function of physiological interventions, it is imperative to measure the levels of these ions in the different organs that are critical in their metabolism. As hemoglobin in blood will react with NO and its metabolites, it is also important to remove blood quickly from tissue samples as much as possible. Thus animals were perfused with saline before collecting skeletal muscle tissues (gluteus, TA, EDL, gastrocnemius muscle), and connective tissue and fat...

Ujawnienia

The authors declare they have no conflicts of interest. Alan N. Schechter is listed as a co-inventor on several patents issued to the National Institutes of Health for the use of nitrite salts for the treatment of cardiovascular diseases. He receives royalties based on NIH licensing of these patents for clinical development but no other compensation. These arrangements do not affect his adherence to JoVE journal policies.

Podziękowania

This work was supported by intramural NIH/NIDDK grant ZIA DK 0251041-14 to Alan N Schechter, MD.

Materiały

NameCompanyCatalog NumberComments
gentleMACS dissociatorMiltenyi Biotec130-093-235
gentle MACS M tubeMiltenyi Biotec130-093-236Length: 87 mm; Diameter: 30 mm
Heparin SodiumHospiraNDC-0409-7620-13
IsofluraneBaxterNDC-10019-360-60
MethanolSigma646377
Minilys bead homogenizerBertin InstrumentsP000673-MLYS0-A
NEM; N-ethylmaleimideSigma4260
Nitric Oxide analyzerGESievers NOA 280i
NP-40; 4-Nonylphenylpolyethylene glycolSigma74385
Potassium ferricyanide; K3Fe(CN)6Sigma702587
Precellys lysing kitBertin InstrumentsP000911-LYSK0-Acontains 2 mL tubes with 2.8 mm ceramic (zirconium oxide) beads for homogenization
Pulverizer kitCellcrusherCellcrusher kit

Odniesienia

  1. Ignarro, L. J. Nitric oxide as a unique signaling molecule in the vascular system: a historical overview. Journal of Physiology and Pharmacology. 53 (4), 503-514 (2002).
  2. Moncada, S., Higgs, A. The L-arginine-nitric oxide pathway. New England Journal of Medicine. 329 (27), 2002-2012 (1993).
  3. Thomas, D. D., Liu, X., Kantrow, S. P., Lancaster, J. R. The biological lifetime of nitric oxide: implications for the perivascular dynamics of NO and O2. Proceedings of the National Academy of Sciences of the United States of America. 98 (1), 355-360 (2001).
  4. Lundberg, J. O., Weitzberg, E., Gladwin, M. T. The nitrate-nitrite-nitric oxide pathway in physiology and therapeutics. Nature Reviews Drug Discovery. 7 (2), 156-167 (2008).
  5. Govoni, M., Jansson, E. A., Weitzberg, E., Lundberg, J. O. The increase in plasma nitrite after a dietary nitrate load is markedly attenuated by an antibacterial mouthwash. Nitric Oxide. 19 (4), 333-337 (2008).
  6. Jansson, E. A., et al. A mammalian functional nitrate reductase that regulates nitrite and nitric oxide homeostasis. Nature Chemical Biology. 4 (7), 411-417 (2008).
  7. Piknova, B., Park, J. W., Kwan Jeff Lam, K., Schechter, A. N. Nitrate as a source of nitrite and nitric oxide during exercise hyperemia in rat skeletal muscle. Nitric Oxide. 55-56, 54-61 (2016).
  8. Cosby, K., et al. Nitrite reduction to nitric oxide by deoxyhemoglobin vasodilates the human circulation. Nature Medicine. 9 (12), 1498-1505 (2003).
  9. Shiva, S., et al. Deoxymyoglobin is a nitrite reductase that generates nitric oxide and regulates mitochondrial respiration. Circulation Research. 100 (5), 654-661 (2007).
  10. Millar, T. M., et al. Xanthine oxidoreductase catalyses the reduction of nitrates and nitrite to nitric oxide under hypoxic conditions. FEBS Letter. 427 (2), 225-228 (1998).
  11. Benjamin, N., et al. Stomach NO synthesis. Nature. 368 (6471), 502 (1994).
  12. Lundberg, J. O., Weitzberg, E., Lundberg, J. M., Alving, K. Intragastric nitric oxide production in humans: measurements in expelled air. Gut. 35 (11), 1543-1546 (1994).
  13. Larsen, F. J., Ekblom, B., Sahlin, K., Lundberg, J. O., Weitzberg, E. Effects of dietary nitrate on blood pressure in healthy volunteers. New England Journal of Medicine. 355 (26), 2792-2793 (2006).
  14. Kapil, V., et al. Inorganic nitrate supplementation lowers blood pressure in humans: role for nitrite-derived NO. Hypertension. 56 (2), 274-281 (2010).
  15. Jones, A. M. Dietary nitrate supplementation and exercise performance. Sports Medicine. 44, 35-45 (2014).
  16. Piknova, B., et al. Skeletal muscle as an endogenous nitrate reservoir. Nitric Oxide. 47, 10-16 (2015).
  17. Wylie, L. J., et al. Human skeletal muscle nitrate store: influence of dietary nitrate supplementation and exercise. Journal of Physiology. 597 (23), 5565-5576 (2019).
  18. Piknova, B., Schechter, A. N. Measurement of nitrite in blood samples using the ferricyanide-based hemoglobin oxidation assay. Methods in Molecular Biology. 704, 39-56 (2011).
  19. Piknova, B., Park, J. W., Cassel, K. S., Gilliard, C. N., Schechter, A. N. Measuring Nitrite and Nitrate, Metabolites in the Nitric Oxide Pathway, in Biological Materials using the Chemiluminescence Method. Journal of Visualized Experiments. (118), e54879 (2016).
  20. Nyakayiru, J., et al. Sodium nitrate ingestion increases skeletal muscle nitrate content in humans. Journal of Applied Physiology. 123 (3), 637-644 (2017).
  21. Troutman, A. D., Gallardo, E. J., Brown, M. B., Coggan, A. R. Measurement of nitrate and nitrite in biopsy-sized muscle samples using HPLC. Journal of Applied Physiology. 125 (5), 1475-1481 (2018).
  22. Shinin, V., Gayraud-Morel, B., Tajbakhsh, S. Template DNA-strand co-segregation and asymmetric cell division in skeletal muscle stem cells. Methods in Molecular Biology. 482, 295-317 (2009).
  23. Long, G. M., Troutman, A. D., Fisher, A., Brown, M. B., Coggan, A. R. Muscle fiber type differences in nitrate and nitrite storage and nitric oxide signaling in rats. bioRxiv. , (2020).
  24. Ohtake, K., et al. Dietary nitrite supplementation improves insulin resistance in type 2 diabetic KKA(y) mice. Nitric Oxide. 44, 31-38 (2015).

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Rat Skeletal MuscleNitrate MeasurementNitrite MeasurementHomogenizationPotassium FerricyanideN methylmaleimideNon ionic SurfactantCentrifugeMethanolSupernatant

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