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An NMT H+ flux profile of Arabidopsis root across several zones. This example shows strong H+ influx closer to the root tip, and slight H+ efflux further from the tip.

Non-invasive micro-test technology (NMT) is a scientific research technology used for measuring physiological events of intact biological samples. NMT is used for research in many biological areas such as gene function, plant physiology, biomedical research, and environmental science. [1] [2]

Most living things experience a constant exchange of ions and molecules with their surroundings as a result of biological processes. NMT uses specialized flux sensors, derived from microelectrodes, to measure this dynamic ion/molecule activity called flux around an intact sample. These fluxes reveal information about physiological phenomena. [1] [2]

Each NMT flux sensor is selective or specific for a particular ion/molecule of choice. Some of the more commonly published ion/molecule flux sensors are those that are commercially available, such as Ca2+, H+, K+, Na+, Cl, Mg2+, Cd2+, NH4+, NO3, Pb2+, Cu2+, O2, H2O2, and IAA (indole-3-acetic acid). [3] [4] [5] [6] [7] [8] [9] Some other flux sensors include glutamate, glucose, Zn2+, Hg2+, and more that have been designed by individual laboratories. [10] [11] [12] [13]

NMT measures how much, how fast, and in what direction the chosen ions/molecules are moving. This is defined as diffusion flux, which is the amount of substance per unit area per unit time. [14]

The principle of how NMT measures flux was described in the 1990s by a few different laboratories; Lionel Jaffe at the Marine Biological Laboratory described the Vibrating Probe technique, [14] and Ian Newman at the University of Tasmania described the MIFE™ technique. [15] There are also technologies SERIS and SIET that use this principle. [16]

Basic procedure

Live sample preparation

Different samples need different amounts of preparation work. For example, small organisms, condensed organelles, and cultured cells, tissues, or organs can be measured with little alteration, but anything below the skin or surface of large organisms must be exposed in order to measure. Generally, once the sample is prepared so that the desired measurement site is revealed, NMT causes no further damage or interference with the test; because of this, NMT is most commonly used for measuring live, intact samples. The live sample must be secured in a Petri dish so it does not move or shift. A single cell can be adhered by means such as a polylysine-coated slide; this also works for other small samples like condensed organelles. [17] Large tissue samples like roots may be weighted down with filter paper and resin tiles. Plenty of other large samples can be measured as well, such as organs or whole small organisms like zebrafish. [18]

An example of raw flux data unfolding as NMT measures oxygen efflux from a leaf sample. During this test, a light is turned on and off periodically, each time causing a change in O2 flux due to photosynthesis.

Liquid media composition

The sample must be surrounded by liquid media, which will be different depending on the sample type, purpose of the test, and ions/molecules that will be measured. This media is a useful way to manipulate the sample's environment by adding things like drugs, stressors, or other biotic/abiotic stimuli. [17]

This step can be the most challenging simply because it allows many possibilities for test manipulation. To get started in designing a specific new test, there is plenty of literature documenting successful composition of liquid media. [19] [20]

Recording

The prepared sample is placed under a microscope with a flux sensor which is controlled by a computer. The operator uses arrow keys to move the flux sensor to the desired point and distance from the sample, aided by a microscope camera. [21]

The NMT flux sensor measures the flux and the data are plotted on-screen during the test. These fluxes are most often measured in the unit 10−12 moles • cm−2 • s−1, or sometimes as small as 10−15 moles • cm−2 • s−1, allowing flux to be measured from something as small as a single cell. [9] [21] During the test, further changes can be introduced like a stressor or other abiotic stimulus, and the flux patterns will change on-screen to show the physiological changes. For example, cold stress can be studied by adding ice-cold test buffer to the solution during testing. [22]

Variations

A picture of what an NMT system may look like. A Faraday cage holds the microscope and flux sensor manipulator to block interference, while a computer system controls and calculates from the outside.

1-dimensional

This is the most common NMT test in which the flux sensor is moved in one direction in reference to the sample, generally perpendicular to the sample boundaries.

2-dimensional

There is not much documented application of 2-dimensional measurement in NMT; the possibility was demonstrated with the Vibrating Probe technique by Degenhardt et al in 1998. [23] They moved the flux sensor both perpendicular and then parallel to a plant root, then summed up the flux vectors to generate the 2-dimensional flux direction. In this kind of manner, NMT can measure 2D fluxes as well, using the same software that measures 3D fluxes. [24]

3-dimensional

One of the pioneers of 3D ion/molecule flux mapping is Joseph Kunkel. [16] To generate a 3-dimensional view of fluxes, the flux sensor must take measurements in the X, Y, and Z directions at each point around a sample. In 2006, a view of H+ and O2 3D flux vectors around a pollen tube was produced using Mageflux software developed by Yue Xu. [25]

A breast tumor sample is measured simultaneously by H+ and O2 flux sensors. The data show how the fluxes change together, which is useful for research in areas like cancer metabolism.

Simultaneous

NMT flux sensors can be set up to measure two or more different ion/molecule fluxes at the same time, allowing the user to see the flux changes simultaneously, and to see the relationship between them. [26] Combining two particular flux measurements simultaneously can be a strong indicator of physiological phenomena. [25] For example, measuring both H+ and O2 simultaneously from a tumor sample (see figure to the right) can provide significant information about cancer metabolism that is far more useful than measuring only one at a time.

Applications

NMT flux sensor measuring a mesophyll cell

Genetics

It is widely accepted that both intracellular and extracellular ionic and molecular activities are vital to many physiological processes, also making them useful indicators of gene functions. By measuring dynamic ion/molecule fluxes, NMT has helped research on genes related to factors such as cold stress, [22] salt tolerance, [27] cadmium uptake, [28] and nutrient uptake in plants. [24] In biomedical genetic research, NMT has measured samples such as liver cells to investigate gene expression through fluxes. [29]

Plant biology

NMT has been widely applied in plant biology in fields such as abiotic/biotic stress, [21] [27] plant nutrition, [24] [30] plant growth and development, [31] plant/microbe interaction, [32] plant defense, [33] photosynthesis, [34] signal transduction research, [35] and more. Roots are commonly measured, in addition to many other plant samples such as leaf tissue, root hairs, guard cells, salt gland cells, mesophyll cells, and condensed organelles like chloroplasts and vacuoles. NMT can help identify plants that are more resistant to stressors like salt, temperature, drought, and disease. [21] [27] It is also a useful tool for studying plant nutrition absorption and regulation mechanisms in ways such as monitoring rates of nutrient uptake at the root surface. [30]

An individual neuron measured by NMT flux sensor

Biomedical

NMT is applied in biomedical research in various fields such as neuroscience, [36] tumor research, [37] drug screening, [38] metabolism, [25] and bone research. [39] NMT is a useful tool for evaluating the effects of treatments for diseases like diabetes and cancer in tissue samples, as it can measure the flux changes in response to treatments. [36] [40] Measured samples include tumor tissue, neurons, brain tissue, liver cells, bone, muscle, and many more. Metabolism rates can be measured by NMT using O2 and H+ fluxes. [25] In bone research, the flux of Ca2+ measured by NMT helps research on bone healing and growth. [40]

Environmental

Various areas of environmental research in which NMT has been applied include water pollution detection, [20] biological early warning, [41] water quality assessment, [42] and heavy metal detection. [6] With global heavy metal pollution of crops on the rise, more NMT heavy metal flux sensors such as Cd2+, Cu2+, and Pb2+ have been used in research to identify plants that can tackle this problem with phytoremediation. [7] For water quality and pollution research, water plants and algae have been measured, as well as biofilms and fish embryos. [43]

See also

References

  1. ^ a b Ding, Y.N.; Xu, Y. (2007). "Non-invasive micro-test technology and its applications in biology and medicine". Physics. 36 (7): 548–558.
  2. ^ a b Zhang, X.; Zhang, X.Y.; Yin, L.P. (2015). "Measurement of H+ flux in Rice by Non-invasive Micro-test Technology" (PDF). Bio-Protocol. 23 (5).
  3. ^ "NMT Physiolyzer®: Features". youngerusa.com. Retrieved 2019-08-16.
  4. ^ "New Products: IAA Measurement System". Science. 362 (6417): 961. 22 November 2018. doi: 10.1126/science.362.6417.961.
  5. ^ Yu, Y.; Xu, T.; Li, X.; Tang, J.; Ma, D.; Li, Z.; Sun, J. (2015). "NaCl-induced changes of ion homeostasis and nitrogen metabolism in two sweet potato (Ipomoea batatas L.) cultivars exhibit different salt tolerance at adventitious root stage". Environmental and Experimental Botany. 129: 23–36. doi: 10.1016/j.envexpbot.2015.12.006.
  6. ^ a b Ma, J.; Cai, H.; He, C.; Zhang, W.; Wang, L. (2015). "A hemicellulose-bound form of silicon inhibits cadmium ion uptake in rice (Oryza sativa) cells". New Phytologist. 206 (3): 1063–1074. doi: 10.1111/nph.13276. PMID  25645894.
  7. ^ a b Li, L.Z.; Yu, S.Y.; Peijnenburg, W.J.G.M.; Luo, Y.M. (2017). "Determining the fluxes of ions (Pb2+, Cu2+ and Cd2+) at the root surface of wetland plants using the scanning ion-selective electrode technique". Plant and Soil. 414 (1–2): 1–12. doi: 10.1007/s11104-016-3109-5. S2CID  35814240.
  8. ^ Li, J.; Pritchard, H.W.; Wang, X. (2014). "The fluxes of H2O2 and O2 can be used to evaluate seed germination and vigor of Caragana korshinskii". Planta. 239 (6): 1363–1373. doi: 10.1007/s00425-014-2049-7. PMID  24659097. S2CID  15444614.
  9. ^ a b Liu, C.Y.; Zhang, F.; Zhang, D.J.; Srivastava, A.K.; Wu, Q.S.; Zou, Y.N. (2018). "Mycorrhiza stimulates root-hair growth and IAA synthesis and transport in trifoliate orange under drought stress". Scientific Reports. 8 (1): 1978. Bibcode: 2018NatSR...8.1978L. doi: 10.1038/s41598-018-20456-4. PMC  5792640. PMID  29386587.
  10. ^ McLamore, E.S.; Mohanty, S.; Shi, J.; Claussen, J.; Jedlicka, S.S.; Rickus, J.L.; Porterfield, D.M. (2010). "A self-referencing glutamate biosensor for measuring real time neuronal glutamate flux". Journal of Neuroscience Methods. 189 (1): 14–22. doi: 10.1016/j.jneumeth.2010.03.001. PMID  20298719. S2CID  41661311.
  11. ^ McLamore, E.S.; Shi, J.; Jaroch, D.; Claussen, J.C.; Uchida, A.; Jiang, Y.; Zhang, W.; Donkin, S.S.; Banks, M.K.; Buhman, K.K.; Teegarden, D.; Rickus, J.L.; Porterfield, D.M. (2011). "A self referencing platinum nanoparticle decorated enzyme-based microbiosensor for real time measurement of physiological glucose transport". Biosensors and Bioelectronics. 26 (5): 2237–2245. doi: 10.1016/j.bios.2010.09.041. PMC  3014447. PMID  20965716.
  12. ^ Lasat, M.M.; Baker, A.; Kochian, L.V. (1996). "Physiological Characterization of Root Zn2+ Absorption and Translocation to Shoots in Zn Hyperaccumulator and Nonaccumulator Species of Thlaspi". Plant Physiology. 112 (4): 1715–1722. doi: 10.1104/pp.112.4.1715. PMC  158105. PMID  12226473.
  13. ^ Hongying, L.V.; Teng, Z.; Wang, S.; Feng, K.; Wang, X.; Wang, C.; Wang, G. (2018). "Voltammetric simultaneous ion flux measurements platform for Cu2+, Pb2+ and Hg2+near rice root surface: Utilizing carbon nitride heterojunction film modified carbon fiber microelectrode". Sensors and Actuators B: Chemical. 256: 98–106. doi: 10.1016/j.snb.2017.10.053.
  14. ^ a b Kühtreiber, W.M.; Jaffe, L.F. (1990). "Detection of extracellular calcium gradients with a calcium specific vibrating electrode". Journal of Cell Biology. 110 (5): 1565–1573. doi: 10.1083/jcb.110.5.1565. PMC  2200169. PMID  2335563.
  15. ^ Ryan, P.R.; Newman, I.A.; Shields, B. (1990). "Ion fluxes in corn roots measured by microelectrodes with ion-specific liquid membranes". Journal of Membrane Science. 53 (1–2): 59–69. doi: 10.1016/0376-7388(90)80006-8.
  16. ^ a b Kunkel, J.G.; Cordeiro, S.; Xu, Y.; Shipley, A.M.; Feijó, J.A. (2006). "Use of Non-Invasive Ion-Selective Microelectrode Techniques for the Study of Plant Development". In Volkov, A.G. (ed.). Plant Electrophysiology. Springer, Berlin, Heidelberg. pp. 109–137. doi: 10.1007/978-3-540-37843-3_5. ISBN  978-3-540-37843-3.
  17. ^ a b Sun, J.; Zhang, X.; Deng, S.; Zhang, C.; Wang, M.; Ding, M.; Zhao, R.; Shen, X.; Zhou, X.; Lu, C.; Chen, S. (2012). "Extracellular ATP Signaling Is Mediated by H2O2 and Cytosolic Ca2+ in the Salt Response of Populus euphratica Cells". PLOS ONE. 7 (12): e53136. Bibcode: 2012PLoSO...753136S. doi: 10.1371/journal.pone.0053136. PMC  3532164. PMID  23285259.
  18. ^ Sun, T.; Xu, Y.; Li, P.; Yu, S.G.; Yin, L.P. (2007). "Non-invasive scanning ion-selective electrode technique and its applications to the research of higher plants". Progress in Natural Science. 17 (6): 625–629. doi: 10.1080/10002007088537450.
  19. ^ Kunkel, J.G; Lin, L.Y.; Xu, Y.; Prado, A.M.M; Feijó, J.A.; Hwang, P.P.; Hepler, P.K. (2001). "The strategic use of Good buffers to measure proton gradients around growing pollen tubes.". In Geitmann, A.; Cresti, M.; Heath, I.B. (eds.). Cell biology of plant and fungal tip growth. IOS Press. pp. 81–94. ISBN  1-58603-083-3.
  20. ^ a b Yang, C.; Fang, S.; Chen, D.; Wang, J.; Liu, F.; Xia, C. (2015). "The possible role of bacterial signal molecules N-acyl homoserine lactones in the formation of diatom-biofilm (Cylindrotheca sp.)". Marine Pollution Bulletin. 107 (1): 118–124. doi: 10.1016/j.marpolbul.2016.04.010. PMID  27090887.
  21. ^ a b c d Jin, Z.; Wang, Z.; Ma, Q.; Sun, L.; Zhang, L.; Liu, Z.; Liu, D.; Hao, X.; Pei, Y. (2017). "Hydrogen sulfide mediates ion fluxes inducing stomatal closure in response to drought stress in Arabidopsis thaliana". Plant and Soil. 419 (1–2): 141–152. doi: 10.1007/s11104-017-3335-5. S2CID  1202467.
  22. ^ a b Ma, Y.; Dai, X.; Xu, Y.; Luo, W.; Zheng, X.; Zheng, D.; Pan, Y.; Lin, X.; Liu, H.; Zhang, D.; Xiao, J.; Guo, X.; Xu, S.; Niu, Y.; Jin, J.; Zhang, H.; Xu, X.; Li, L.; Wang, W.; Qian, Q.; Ge, S.; Chong, K. (2015). "COLD1 Confers Chilling Tolerance in Rice". Cell. 160 (6): 1209–1221. doi: 10.1016/j.cell.2015.01.046. PMID  25728666.
  23. ^ Degenhardt, J.; Larsen, P.B.; Howell, S.H.; Kochian, L.V. (1998). "Aluminum Resistance in the Arabidopsis Mutantalr-104 Is Caused by an Aluminum-Induced Increase in Rhizosphere pH". Plant Physiology. 117 (1): 19–27. doi: 10.1104/pp.117.1.19. PMC  35003. PMID  9576770.
  24. ^ a b c Dai, J.L.; Duan, L.S.; Dong, H.Z. (2015). "Comparative Effect of Nitrogen Forms on Nitrogen Uptake and Cotton Growth Under Salinity Stress". Journal of Plant Nutrition. 38 (10): 1530–1543. doi: 10.1080/01904167.2014.983126. S2CID  102046468.
  25. ^ a b c d Xu, Y.; Sun, T.; Yin, L.P. (2006). "Application of non-invasive microsensing system to simultaneously measure both H+ and O2 fluxes around the pollen tube". Journal of Integrative Plant Biology. 48 (7): 823–831. doi: 10.1111/j.1744-7909.2006.00281.x.
  26. ^ Garnett, T.P.; Shabala, S.N.; Smethurst, P.J.; Newman, I.A. (2003). "Kinetics of ammonium and nitrate uptake by eucalypt roots and associated proton fluxes measured using ion selective microelectrodes". Functional Plant Biology. 30 (11): 1165–1176. doi: 10.1071/FP03087. PMID  32689098.
  27. ^ a b c Li, S.; Liu, J.; An, Y.; Cao, Y.; Liu, Y.; Zhang, J.; Geng, J.; Hu, T.; Yang, P. (2019). "MsPIP2;2, a novel aquaporin gene from Medicago sativa, confers salt tolerance in transgenic Arabidopsis". Environmental and Experimental Botany. 165: 39–52. doi: 10.1016/j.envexpbot.2019.05.020. S2CID  190879634.
  28. ^ Wang, J.; Liang, S.; Xiang, W.; Dai, H.; Duan, Y.; Kang, F.; Chai, T. (2019). "A repeat region from the Brassica juncea HMA4 gene BjHMA4R is specifically involved in Cd2+ binding in the cytosol under low heavy metal concentrations". BMC Plant Biology. 19 (1): 89. doi: 10.1186/s12870-019-1674-5. PMC  6394093. PMID  30819104.
  29. ^ Zhang, Z.Y.; Wang, W.J.; Pan, L.J.; Xu, Y.; Zhang, Z.M. (2009). "Measuring Ca2+ influxes of TRPC1-dependent Ca2+ channels in HL-7702 cells with Non-invasive Micro-test Technique". World Journal of Gastroenterology. 15 (33): 4150–4155. doi: 10.3748/wjg.15.4150. PMC  2738811. PMID  19725149.
  30. ^ a b Zhang, Y.; Zhou, Y.; Chen, S.; Liu, J.; Fan, K.; Li, Z.; Liu, Z.; Lin, W. (2019). "Gibberellins play dual roles in response to phosphate starvation of tomato seedlings, negatively in shoots but positively in roots". Journal of Plant Physiology. 234–235: 145–153. doi: 10.1016/j.jplph.2019.02.007. PMID  30807885. S2CID  73482807.
  31. ^ Zhang, F.; Wang, P.; Zou, Y.N.; Wu, Q.S.; Kuča, K. (2019). "Effects of mycorrhizal fungi on root-hair growth and hormone levels of taproot and lateral roots in trifoliate orange under drought stress". Archives of Agronomy and Soil Science. 65 (9): 1316–1330. doi: 10.1080/03650340.2018.1563780. S2CID  91980172.
  32. ^ Wang, X.; Teng, Y.; Tu, C.; Luo, Y.; Greening, X.; Zhang, N.; Dai, S.; Ren, W.; Zhao, L.; Li, Z. (2018). "Coupling between Nitrogen Fixation and Tetrachlorobiphenyl Dechlorination in a Rhizobium−Legume Symbiosis". Environmental Science & Technology. 52 (4): 2217–2224. Bibcode: 2018EnST...52.2217W. doi: 10.1021/acs.est.7b05667. PMID  29363956.
  33. ^ Cui, Y.; Li, X.; Yu, M.; Li, R.; Fan, L.; Zhu, Y.; Lin, J. (2018). "Sterols regulate endocytic pathways during flg22-induced defense responses in Arabidopsis". Development. 145 (19): dev165688. doi: 10.1242/dev.165688. PMID  30228101. S2CID  52297119.
  34. ^ Chen, P.; Yan, K.; Shao, H.; Zhao, S. (2013). "Physiological Mechanisms for High Salt Tolerance in Wild Soybean (Glycine soja) from Yellow River Delta, China: Photosynthesis, Osmotic Regulation, Ion Flux and antioxidant Capacity". PLOS ONE. 8 (12): e83227. Bibcode: 2013PLoSO...883227C. doi: 10.1371/journal.pone.0083227. PMC  3861505. PMID  24349468.
  35. ^ Zhao, C.C.; Wang, Y.; Chan, K.X.; Marchant, D.B.; Franks, P.J.; Randall, D.; Tee, E.E.; Chen, G.; Ramesh, S.; Phua, S.Y.; Zhang, B.; Hills, A.; Dai, F.; Xue, D.; Gilliham, M.; Tyerman, S.; Nevo, E.; Wu, F.; Zhang, G.; Wong, G.K.S.; Leebens-Mack, J.H.; Melkonian, M.; Blatt, M.R.; Soltis, P.S.; Soltis, D.E.; Pogson, B.J.; Chen, Z.H. (2019). "Evolution of chloroplast retrograde signaling facilitates green plant adaptation to land". PNAS. 116 (11): 5015–5020. doi: 10.1073/pnas.1812092116. PMC  6421419. PMID  30804180.
  36. ^ a b Li, T.; Yuan, L.; Zhang, J.; Jiao, J.J.; Qi, J.S. (2017). "Real-time measurement of Ca2+ flux in hippocampal slice with non-invasive micro-test technique". Acta Physiologica Sinica. 69 (4): 467–476. doi: 10.13294/j.aps.2017.0033. PMID  28825106.
  37. ^ Hu, S.L.; Du, P.; Hu, R.; Li, F.; Feng, H. (2014). "Imbalance of Ca2+ and K+ fluxes in C6 glioma cells after PDT measured with scanning ion-selective electrode technique". Lasers in Medical Science. 29 (3): 1261–1267. doi: 10.1007/s10103-014-1518-3. PMID  24458531. S2CID  22174597.
  38. ^ Jin, S.; Yong, T.; Ping, Z. (2008). "Direct evidence for the correlation between extracellular H+ activities and drug-resistance of tumor cells by non-invasive micro-test technique". Acta Biophysica Sinica. 24 (3): 191–197.
  39. ^ Liu, W.; Dan, X.; Lu, W.W.; Zhao, X.; Ruan, C.; Wang, T.; Cui, X.; Zhai, X.; Ma, Y.; Wang, D.; Huang, W.; Pan, H (2019). "Spatial Distribution of Biomaterial Microenvironment pH and Its Modulatory Effect on Osteoclasts at the Early Stage of Bone Defect Regeneration". ACS Appl Mater Interfaces. 11 (9): 9557–9572. doi: 10.1021/acsami.8b20580. PMID  30720276. S2CID  73416100.
  40. ^ a b Li, F.; Porterfield, D.M.; Zheng, X.Y.; Wang, W.J.; Xu, Y.; Zhang, Z.M. (2012). "Abnormal mitochondrial function impairs calcium influx in diabetic mouse pancreatic beta cells". Chinese Medical Journal. 125 (3): 502–510. doi: 10.3760/cma.j.issn.0366-6999.2012.03.019. PMID  22490411.
  41. ^ Sanchez, B.C.; Ochao-Acuña, H.; Porterfield, D.M.; Sepúlveda, M.S. (2008). "Oxygen Flux As an Indicator of Physiological Stress in Fathead Minnow (Pimephales promelas) Embryos: A Real-Time Biomonitoring System of Water Quality". Environmental Science & Technology. 42 (18): 7010–7017. Bibcode: 2008EnST...42.7010S. doi: 10.1021/es702879t. PMID  18853824.
  42. ^ Ma, J.; Zhou, B.; Duan, D.; Wei, Y.; Pan, K. (2018). "Silicon limitation reduced the adsorption of cadmium in marine diatoms". Aquatic Toxicology. 202: 136–144. doi: 10.1016/j.aquatox.2018.07.011. PMID  30031253. S2CID  51710733.
  43. ^ Horng, J.L.; Chao, P.L.; Chen, P.Y.; Shih, T.H.; Lin, L.Y. (2015). "Aquaporin 1 Is Involved in Acid Secretion by Ionocytes of Zebrafish Embryos through Facilitating CO2 Transport". PLOS ONE. 10 (8): e0136440. Bibcode: 2015PLoSO..1036440H. doi: 10.1371/journal.pone.0136440. PMC  4546062. PMID  26287615.
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