Sodium transport and phosphorus metabolism in sodium-loaded yeast: simultaneous observation with sodium-23 and phosphorus-31 NMR spectroscopy in vivo
Simultaneous 23Na and 31P NMR spectra were obtained from a number of yeast suspensions. Prior to NMR spectroscopy, the yeast cells were Na-loaded: this replaced some of the intracellular K+ with Na+. These cells were also somewhat P-deficient in that they had no polyphosphate species visible in the...
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| Veröffentlicht in: | Biochemistry (Easton) 1987-08, Vol.26 (16), p.4953-4962 |
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| creator | Hoefeler, Herbert Jensen, Dye Pike, Martin M Delayre, Jean L Cirillo, Vincent P Springer, Charles S Fossel, Eric T Balschi, James A |
| description | Simultaneous 23Na and 31P NMR spectra were obtained from a number of yeast suspensions. Prior to NMR spectroscopy, the yeast cells were Na-loaded: this replaced some of the intracellular K+ with Na+. These cells were also somewhat P-deficient in that they had no polyphosphate species visible in the 31P NMR spectrum. In the NMR experiments, the Na-loaded cells were suspended in media which contained inorganic phosphate, very low Na+, and a shift reagent for the Na+ NMR signal. The media differed as to whether dioxygen, glucose, or K+ was present individually or in combinations and as to whether the medium was buffered or not. The NMR spectra revealed that the cells always lost Na+ and gained phosphorus. However, the nature of the Na+ efflux time course and the P metabolism differed depending on the medium. The Na+ efflux usually proceeded linearly until the amount of Na+ extruded roughly equalled the amount of NH4+ and orthophosphate initially present in the medium (external phosphate was added as NH4H2PO4). Thus, we presume this first phase reflects a Na+ for NH4+ exchange. The Na+ efflux then entered a transition phase, either slowing, ceasing, or transiently reversing, before resuming at about the same value as that of the first phase. We presume that this last phase involves the simultaneous extrusion of intracellular anions as reported in the literature. The phosphorus metabolism was much more varied. In the absence of exogenous glucose, the P taken up accumulated first as intracellular inorganic phosphate; otherwise, it accumulated first in the "sugar phosphate" pool. In most cases, at least some of the P left the sugar phosphate pool and entered the polyphosphate reservoir in the vacuole. However, this never happened until the phase probably representing Na+ for NH4+ exchange was completed, and the P in the polyphosphate pool never remained there permanently but always eventually reverted back to the sugar phosphate pool. These changes are interpreted in terms of hierarchical energy demands on the cells under the different conditions. In particular, the energy for the Na+ for NH4+ exchange takes precedence over that required to produce and store polyphosphate. This conclusion is supported by the fact that when the cells are "forced" to exchange K+, as well as NH4+, for Na+ (by the addition of 5 times as much K+ to the NH4+-containing medium), polyphosphates are never significantly formed, and the initial linear Na+ efflux phase persists possibly 6 ti |
| doi_str_mv | 10.1021/bi00390a011 |
| format | Article |
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Prior to NMR spectroscopy, the yeast cells were Na-loaded: this replaced some of the intracellular K+ with Na+. These cells were also somewhat P-deficient in that they had no polyphosphate species visible in the 31P NMR spectrum. In the NMR experiments, the Na-loaded cells were suspended in media which contained inorganic phosphate, very low Na+, and a shift reagent for the Na+ NMR signal. The media differed as to whether dioxygen, glucose, or K+ was present individually or in combinations and as to whether the medium was buffered or not. The NMR spectra revealed that the cells always lost Na+ and gained phosphorus. However, the nature of the Na+ efflux time course and the P metabolism differed depending on the medium. The Na+ efflux usually proceeded linearly until the amount of Na+ extruded roughly equalled the amount of NH4+ and orthophosphate initially present in the medium (external phosphate was added as NH4H2PO4). Thus, we presume this first phase reflects a Na+ for NH4+ exchange. The Na+ efflux then entered a transition phase, either slowing, ceasing, or transiently reversing, before resuming at about the same value as that of the first phase. We presume that this last phase involves the simultaneous extrusion of intracellular anions as reported in the literature. The phosphorus metabolism was much more varied. In the absence of exogenous glucose, the P taken up accumulated first as intracellular inorganic phosphate; otherwise, it accumulated first in the "sugar phosphate" pool. In most cases, at least some of the P left the sugar phosphate pool and entered the polyphosphate reservoir in the vacuole. However, this never happened until the phase probably representing Na+ for NH4+ exchange was completed, and the P in the polyphosphate pool never remained there permanently but always eventually reverted back to the sugar phosphate pool. These changes are interpreted in terms of hierarchical energy demands on the cells under the different conditions. In particular, the energy for the Na+ for NH4+ exchange takes precedence over that required to produce and store polyphosphate. This conclusion is supported by the fact that when the cells are "forced" to exchange K+, as well as NH4+, for Na+ (by the addition of 5 times as much K+ to the NH4+-containing medium), polyphosphates are never significantly formed, and the initial linear Na+ efflux phase persists possibly 6 times as long.</description><identifier>ISSN: 0006-2960</identifier><identifier>EISSN: 1520-4995</identifier><identifier>DOI: 10.1021/bi00390a011</identifier><identifier>PMID: 3311159</identifier><language>eng</language><publisher>Washington, DC: American Chemical Society</publisher><subject>550601 - Medicine- Unsealed Radionuclides in Diagnostics ; Aerobiosis ; ALKALI METAL ISOTOPES ; Anaerobiosis ; Applied sciences ; ATP ; Biological Transport, Active ; Exact sciences and technology ; FUNGI ; ISOTOPES ; Kinetics ; LIGHT NUCLEI ; MAGNETIC RESONANCE ; Magnetic Resonance Spectroscopy - methods ; MEMBRANE TRANSPORT ; METABOLISM ; MICROORGANISMS ; Models, Biological ; NMR SPECTRA ; NUCLEAR MAGNETIC RESONANCE ; NUCLEI ; NUCLEOTIDES ; ODD-EVEN NUCLEI ; ORGANIC COMPOUNDS ; Other techniques and industries ; Phosphates - metabolism ; Phosphorus ; PHOSPHORUS 31 ; PHOSPHORUS ISOTOPES ; PLANTS ; RADIOLOGY AND NUCLEAR MEDICINE ; RESONANCE ; Saccharomyces cerevisiae ; Saccharomyces cerevisiae - metabolism ; sodium ; Sodium - metabolism ; SODIUM 23 ; SODIUM ISOTOPES ; SPECTRA ; STABLE ISOTOPES ; TIME DEPENDENCE ; YEASTS</subject><ispartof>Biochemistry (Easton), 1987-08, Vol.26 (16), p.4953-4962</ispartof><rights>1988 INIST-CNRS</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-a356t-294a800f80dddef347aa808d46ffc2a43874bbd8771d8fbaefe2b2cefc22f9403</citedby></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://pubs.acs.org/doi/pdf/10.1021/bi00390a011$$EPDF$$P50$$Gacs$$H</linktopdf><linktohtml>$$Uhttps://pubs.acs.org/doi/10.1021/bi00390a011$$EHTML$$P50$$Gacs$$H</linktohtml><link.rule.ids>314,780,784,885,2763,27074,27922,27923,56736,56786</link.rule.ids><backlink>$$Uhttp://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=7844754$$DView record in Pascal Francis$$Hfree_for_read</backlink><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/3311159$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink><backlink>$$Uhttps://www.osti.gov/biblio/5878196$$D View this record in Osti.gov$$Hfree_for_read</backlink></links><search><creatorcontrib>Hoefeler, Herbert</creatorcontrib><creatorcontrib>Jensen, Dye</creatorcontrib><creatorcontrib>Pike, Martin M</creatorcontrib><creatorcontrib>Delayre, Jean L</creatorcontrib><creatorcontrib>Cirillo, Vincent P</creatorcontrib><creatorcontrib>Springer, Charles S</creatorcontrib><creatorcontrib>Fossel, Eric T</creatorcontrib><creatorcontrib>Balschi, James A</creatorcontrib><creatorcontrib>Harvard Medical School, Boston, MA</creatorcontrib><title>Sodium transport and phosphorus metabolism in sodium-loaded yeast: simultaneous observation with sodium-23 and phosphorus-31 NMR spectroscopy in vivo</title><title>Biochemistry (Easton)</title><addtitle>Biochemistry</addtitle><description>Simultaneous 23Na and 31P NMR spectra were obtained from a number of yeast suspensions. Prior to NMR spectroscopy, the yeast cells were Na-loaded: this replaced some of the intracellular K+ with Na+. These cells were also somewhat P-deficient in that they had no polyphosphate species visible in the 31P NMR spectrum. In the NMR experiments, the Na-loaded cells were suspended in media which contained inorganic phosphate, very low Na+, and a shift reagent for the Na+ NMR signal. The media differed as to whether dioxygen, glucose, or K+ was present individually or in combinations and as to whether the medium was buffered or not. The NMR spectra revealed that the cells always lost Na+ and gained phosphorus. However, the nature of the Na+ efflux time course and the P metabolism differed depending on the medium. The Na+ efflux usually proceeded linearly until the amount of Na+ extruded roughly equalled the amount of NH4+ and orthophosphate initially present in the medium (external phosphate was added as NH4H2PO4). Thus, we presume this first phase reflects a Na+ for NH4+ exchange. The Na+ efflux then entered a transition phase, either slowing, ceasing, or transiently reversing, before resuming at about the same value as that of the first phase. We presume that this last phase involves the simultaneous extrusion of intracellular anions as reported in the literature. The phosphorus metabolism was much more varied. In the absence of exogenous glucose, the P taken up accumulated first as intracellular inorganic phosphate; otherwise, it accumulated first in the "sugar phosphate" pool. In most cases, at least some of the P left the sugar phosphate pool and entered the polyphosphate reservoir in the vacuole. However, this never happened until the phase probably representing Na+ for NH4+ exchange was completed, and the P in the polyphosphate pool never remained there permanently but always eventually reverted back to the sugar phosphate pool. These changes are interpreted in terms of hierarchical energy demands on the cells under the different conditions. In particular, the energy for the Na+ for NH4+ exchange takes precedence over that required to produce and store polyphosphate. This conclusion is supported by the fact that when the cells are "forced" to exchange K+, as well as NH4+, for Na+ (by the addition of 5 times as much K+ to the NH4+-containing medium), polyphosphates are never significantly formed, and the initial linear Na+ efflux phase persists possibly 6 times as long.</description><subject>550601 - Medicine- Unsealed Radionuclides in Diagnostics</subject><subject>Aerobiosis</subject><subject>ALKALI METAL ISOTOPES</subject><subject>Anaerobiosis</subject><subject>Applied sciences</subject><subject>ATP</subject><subject>Biological Transport, Active</subject><subject>Exact sciences and technology</subject><subject>FUNGI</subject><subject>ISOTOPES</subject><subject>Kinetics</subject><subject>LIGHT NUCLEI</subject><subject>MAGNETIC RESONANCE</subject><subject>Magnetic Resonance Spectroscopy - methods</subject><subject>MEMBRANE TRANSPORT</subject><subject>METABOLISM</subject><subject>MICROORGANISMS</subject><subject>Models, Biological</subject><subject>NMR SPECTRA</subject><subject>NUCLEAR MAGNETIC RESONANCE</subject><subject>NUCLEI</subject><subject>NUCLEOTIDES</subject><subject>ODD-EVEN NUCLEI</subject><subject>ORGANIC COMPOUNDS</subject><subject>Other techniques and industries</subject><subject>Phosphates - metabolism</subject><subject>Phosphorus</subject><subject>PHOSPHORUS 31</subject><subject>PHOSPHORUS ISOTOPES</subject><subject>PLANTS</subject><subject>RADIOLOGY AND NUCLEAR MEDICINE</subject><subject>RESONANCE</subject><subject>Saccharomyces cerevisiae</subject><subject>Saccharomyces cerevisiae - metabolism</subject><subject>sodium</subject><subject>Sodium - metabolism</subject><subject>SODIUM 23</subject><subject>SODIUM ISOTOPES</subject><subject>SPECTRA</subject><subject>STABLE ISOTOPES</subject><subject>TIME DEPENDENCE</subject><subject>YEASTS</subject><issn>0006-2960</issn><issn>1520-4995</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1987</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqFkU-L1TAUxYso4zi6ci0EEV1INWnSJnUngzMKoz6cpws3Ic0fXsa2qbnp0_dB_L5m7PMhIrgI4XJ-OffenKK4T_AzgivyvPMY0xYrTMiN4pjUFS5Z29Y3i2OMcVNWbYNvF3cArnLJMGdHxRGlhJC6PS5-XAbj5wGlqEaYQkxIjQZNmwD5xBnQYJPqQu9hQH5E8Isu-6CMNWhnFaQXCPww90mNNmQ-dGDjViUfRvTNp83vJxX9y7mkBL17-wHBZHWKAXSYdtcttn4b7ha3nOrB3tvfJ8XHs1fr09flxfvzN6cvL0pF6yblzZgSGDuBjTHWUcZVroVhjXO6UowKzrrOCM6JEa5T1tmqq7TNYuVahulJ8XDxDZC8BO2T1RsdxjGPJGvBBWmbDD1eoCmGr7OFJAcP2vb9srEUBNck_-t_QcIEow0jGXy6gDrvDdE6OUU_qLiTBMvrSOUfkWb6wd527gZrDuw-w6w_2usKtOpdTlJ7OGBcMMZrlrFywTwk-_0gq_hFNpzyWq5Xl_KcnvHPq_VKfsr8k4VXGuRVmOOYk_jngD8B1wTHSQ</recordid><startdate>19870811</startdate><enddate>19870811</enddate><creator>Hoefeler, Herbert</creator><creator>Jensen, Dye</creator><creator>Pike, Martin M</creator><creator>Delayre, Jean L</creator><creator>Cirillo, Vincent P</creator><creator>Springer, Charles S</creator><creator>Fossel, Eric T</creator><creator>Balschi, James A</creator><general>American Chemical Society</general><scope>BSCLL</scope><scope>IQODW</scope><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>8FD</scope><scope>FR3</scope><scope>M7N</scope><scope>M7Z</scope><scope>P64</scope><scope>7X8</scope><scope>OTOTI</scope></search><sort><creationdate>19870811</creationdate><title>Sodium transport and phosphorus metabolism in sodium-loaded yeast: simultaneous observation with sodium-23 and phosphorus-31 NMR spectroscopy in vivo</title><author>Hoefeler, Herbert ; Jensen, Dye ; Pike, Martin M ; Delayre, Jean L ; Cirillo, Vincent P ; Springer, Charles S ; Fossel, Eric T ; Balschi, James A</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a356t-294a800f80dddef347aa808d46ffc2a43874bbd8771d8fbaefe2b2cefc22f9403</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>1987</creationdate><topic>550601 - Medicine- Unsealed Radionuclides in Diagnostics</topic><topic>Aerobiosis</topic><topic>ALKALI METAL ISOTOPES</topic><topic>Anaerobiosis</topic><topic>Applied sciences</topic><topic>ATP</topic><topic>Biological Transport, Active</topic><topic>Exact sciences and technology</topic><topic>FUNGI</topic><topic>ISOTOPES</topic><topic>Kinetics</topic><topic>LIGHT NUCLEI</topic><topic>MAGNETIC RESONANCE</topic><topic>Magnetic Resonance Spectroscopy - methods</topic><topic>MEMBRANE TRANSPORT</topic><topic>METABOLISM</topic><topic>MICROORGANISMS</topic><topic>Models, Biological</topic><topic>NMR SPECTRA</topic><topic>NUCLEAR MAGNETIC RESONANCE</topic><topic>NUCLEI</topic><topic>NUCLEOTIDES</topic><topic>ODD-EVEN NUCLEI</topic><topic>ORGANIC COMPOUNDS</topic><topic>Other techniques and industries</topic><topic>Phosphates - metabolism</topic><topic>Phosphorus</topic><topic>PHOSPHORUS 31</topic><topic>PHOSPHORUS ISOTOPES</topic><topic>PLANTS</topic><topic>RADIOLOGY AND NUCLEAR MEDICINE</topic><topic>RESONANCE</topic><topic>Saccharomyces cerevisiae</topic><topic>Saccharomyces cerevisiae - metabolism</topic><topic>sodium</topic><topic>Sodium - metabolism</topic><topic>SODIUM 23</topic><topic>SODIUM ISOTOPES</topic><topic>SPECTRA</topic><topic>STABLE ISOTOPES</topic><topic>TIME DEPENDENCE</topic><topic>YEASTS</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Hoefeler, Herbert</creatorcontrib><creatorcontrib>Jensen, Dye</creatorcontrib><creatorcontrib>Pike, Martin M</creatorcontrib><creatorcontrib>Delayre, Jean L</creatorcontrib><creatorcontrib>Cirillo, Vincent P</creatorcontrib><creatorcontrib>Springer, Charles S</creatorcontrib><creatorcontrib>Fossel, Eric T</creatorcontrib><creatorcontrib>Balschi, James A</creatorcontrib><creatorcontrib>Harvard Medical School, Boston, MA</creatorcontrib><collection>Istex</collection><collection>Pascal-Francis</collection><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>Technology Research Database</collection><collection>Engineering Research Database</collection><collection>Algology Mycology and Protozoology Abstracts (Microbiology C)</collection><collection>Biochemistry Abstracts 1</collection><collection>Biotechnology and BioEngineering Abstracts</collection><collection>MEDLINE - Academic</collection><collection>OSTI.GOV</collection><jtitle>Biochemistry (Easton)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Hoefeler, Herbert</au><au>Jensen, Dye</au><au>Pike, Martin M</au><au>Delayre, Jean L</au><au>Cirillo, Vincent P</au><au>Springer, Charles S</au><au>Fossel, Eric T</au><au>Balschi, James A</au><aucorp>Harvard Medical School, Boston, MA</aucorp><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Sodium transport and phosphorus metabolism in sodium-loaded yeast: simultaneous observation with sodium-23 and phosphorus-31 NMR spectroscopy in vivo</atitle><jtitle>Biochemistry (Easton)</jtitle><addtitle>Biochemistry</addtitle><date>1987-08-11</date><risdate>1987</risdate><volume>26</volume><issue>16</issue><spage>4953</spage><epage>4962</epage><pages>4953-4962</pages><issn>0006-2960</issn><eissn>1520-4995</eissn><abstract>Simultaneous 23Na and 31P NMR spectra were obtained from a number of yeast suspensions. Prior to NMR spectroscopy, the yeast cells were Na-loaded: this replaced some of the intracellular K+ with Na+. These cells were also somewhat P-deficient in that they had no polyphosphate species visible in the 31P NMR spectrum. In the NMR experiments, the Na-loaded cells were suspended in media which contained inorganic phosphate, very low Na+, and a shift reagent for the Na+ NMR signal. The media differed as to whether dioxygen, glucose, or K+ was present individually or in combinations and as to whether the medium was buffered or not. The NMR spectra revealed that the cells always lost Na+ and gained phosphorus. However, the nature of the Na+ efflux time course and the P metabolism differed depending on the medium. The Na+ efflux usually proceeded linearly until the amount of Na+ extruded roughly equalled the amount of NH4+ and orthophosphate initially present in the medium (external phosphate was added as NH4H2PO4). Thus, we presume this first phase reflects a Na+ for NH4+ exchange. The Na+ efflux then entered a transition phase, either slowing, ceasing, or transiently reversing, before resuming at about the same value as that of the first phase. We presume that this last phase involves the simultaneous extrusion of intracellular anions as reported in the literature. The phosphorus metabolism was much more varied. In the absence of exogenous glucose, the P taken up accumulated first as intracellular inorganic phosphate; otherwise, it accumulated first in the "sugar phosphate" pool. In most cases, at least some of the P left the sugar phosphate pool and entered the polyphosphate reservoir in the vacuole. However, this never happened until the phase probably representing Na+ for NH4+ exchange was completed, and the P in the polyphosphate pool never remained there permanently but always eventually reverted back to the sugar phosphate pool. These changes are interpreted in terms of hierarchical energy demands on the cells under the different conditions. In particular, the energy for the Na+ for NH4+ exchange takes precedence over that required to produce and store polyphosphate. This conclusion is supported by the fact that when the cells are "forced" to exchange K+, as well as NH4+, for Na+ (by the addition of 5 times as much K+ to the NH4+-containing medium), polyphosphates are never significantly formed, and the initial linear Na+ efflux phase persists possibly 6 times as long.</abstract><cop>Washington, DC</cop><pub>American Chemical Society</pub><pmid>3311159</pmid><doi>10.1021/bi00390a011</doi><tpages>10</tpages></addata></record> |
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| ispartof | Biochemistry (Easton), 1987-08, Vol.26 (16), p.4953-4962 |
| issn | 0006-2960 1520-4995 |
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| subjects | 550601 - Medicine- Unsealed Radionuclides in Diagnostics Aerobiosis ALKALI METAL ISOTOPES Anaerobiosis Applied sciences ATP Biological Transport, Active Exact sciences and technology FUNGI ISOTOPES Kinetics LIGHT NUCLEI MAGNETIC RESONANCE Magnetic Resonance Spectroscopy - methods MEMBRANE TRANSPORT METABOLISM MICROORGANISMS Models, Biological NMR SPECTRA NUCLEAR MAGNETIC RESONANCE NUCLEI NUCLEOTIDES ODD-EVEN NUCLEI ORGANIC COMPOUNDS Other techniques and industries Phosphates - metabolism Phosphorus PHOSPHORUS 31 PHOSPHORUS ISOTOPES PLANTS RADIOLOGY AND NUCLEAR MEDICINE RESONANCE Saccharomyces cerevisiae Saccharomyces cerevisiae - metabolism sodium Sodium - metabolism SODIUM 23 SODIUM ISOTOPES SPECTRA STABLE ISOTOPES TIME DEPENDENCE YEASTS |
| title | Sodium transport and phosphorus metabolism in sodium-loaded yeast: simultaneous observation with sodium-23 and phosphorus-31 NMR spectroscopy in vivo |
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