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Mg Atp

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Aurelian Udristioiu
Aurelian Udristioiu
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Role of Ion Mg as Cofactor ATP in Assurance of Energetic Environment Cells Aurelian Udristioiu, Clinical Laboratory, Medical Analyses Emergency County Hospital Targu Jiu
Magnesium is an essential element in biological systems. Magnesium occurs typically as the Mg2+ ion. It is an essential mineral nutrient for life and is present in every cell type in every organism. For example, ATP (adenosine triphosphate), the main source of energy in cells, must be bound to a magnesium ion in order to be biologically active. What is called ATP is often actually Mg-ATP. Mg to Cell membranes Biological cell membranes and cell walls are poly- anionic surfaces. This has important implications for the transport of ions, particularly because it has been shown that different membranes preferentially bind different ions. Both Mg2+ and Ca2+ regularly stabilize membranes by the cross-linking of carboxylated and phosphorylated head groups of lipids.
The transport of ions is dependent on both the concentration gradient of the ion and the electric potential (ΔΨ) across the membrane, which will be affected by the charge on the membrane surface. The entry of Mg2+ into cells may occur through one of two pathways, via channels using the ΔΨ (negative inside) across this membrane or by support with H+ ions. A schematic of a plant cell is shown including the four major compartments currently recognition as interacting with Mg2+, H+- ATPases maintains a constant ΔpH across the plasma membrane and the vacuole membrane. Mg2+ is transported into the vacuole using the energy of ΔpH. The transport of Mg2+ into mitochondria probably uses ΔΨ and it is likely with chloroplasts which take Mg2+ by a similar system. Magnesium ions can be critical in maintaining the positional integrity of closely clustered phosphate groups. These clusters appear in numerous and distinct parts of the cell nucleus and cytoplasm. Figure 1
Figure 1: Magnesium in the plant cell
Mg and ANAEROBIC METABOLISM in CYTOPLASM OF CELLS In all alive bodies immediated energy sources there are process of oxidation of glucose. In biochemical processes of Anaerobic. Metabolism, the donor of phosphate group is ATP and the reaction is catalyzed of the enzymes hexokinase or glucokinase. hexokinase Glucose +ATP=Glucose-6-phosphate Mg (DGo = -3.4kal/mol). The process of transformation of glucose-6-phosphate in fructose-6- phosphate is catalyzed by enzyme phospho-glucomutase, having as and co-factor ATP+Mg. In fellow step,transformation G-6-phosphate in F-1-6-biphophate, under the action of enzyme phosphofructokinase, reactant is ATP-Mg, and the reaction have place with decrease of free energy, being un-reversible in cellular normal conditions in sequence of glicolitc degradation.
In twice steady of glicolyse, the acid phopho-enolpiruvic, in present of Mg²+ and K+ is transformed in piruvic acid. In cancer cells or in absence of oxygen have place the transformation piruvic acid in lactic acid and the glicolyse stop here. The energetic sum of anaerobic-glicolyse is total DG0 = -34.64 kcal/mol but the molecule of glucose contain 686 kcal/mol and the difference (-654 .51 kcal ) can remains a potential for un-controlled reactions in carcinogenesis. Lack of Mg in one of reaction of anaerobic glicolyse, can block the transformation of anaerobic process in aerobic process and the carcinogenetic process will be installed on via pentozo-phosphate away( G-6-P + NADPH+ - RIBOZA – 5 –P + CO2 + NAPHH+ 2H+). The pentose way is a strategic steps for malign cell with multiple syntheses of nucleic acids, without ATP consume, in build of purine bases necessary in build of sequences of AND.
CITOPLASM CELLS-AEROBIC METABOLISM In Aerobic Glucose Metabolism, acid citric oxidation is helped of ADP and Mg²+ increases speed of reaction: Iso-citric acid + NADP (NAD) ---isocitrat-dehidrogenase = alpha-ceto-glutaric acid. Finally, in a health cell, will be delivery -299.06 kcal(71.54 KJ), minim level of energy for alive cells being 60 KJ, corresponding to a potential membrane of +- 60-90 mEv, the difference from 654.51 kcal will be lost by reversible reactions. Role of ATP-Mg to Mitocondryal Level To level of mitochondria the gradient of pH and potential membrane means “motrice force” of proton which is necessary in ATP synthesis from Krebs cycle. The concentration of H+ become high in place of mitocondrial cytosolic and a electric potential is born in this place. This proton of “ motric force”, of 0.22 mEv, correspond to a level of free energy de 5.2 Kcal/ proton molecule. The transfer of electron from NADPH in each every place of conserved energy transmit conformational exchanges of mitocondrial enzymes. Scheme 1. Graphic 1
SCHEME 1
• Changes in pH value into fluids of cells can occur because inversion of electron spin, to hydrogen atoms, with increase of energy to electrophil oxygen atom from H2O molecules, becoming trigger for levogir vibrational molecules, as the estimation: H-O-H>>H-O-H±. • The energy of parallel spin at electron from fundamental position (unexciting) will be increased to anti-parallel position spin (exciting) in value of 0.04*10³ meV. The energy of oscillation for hydrogen atom is in water is in value of 0.04*10_5 meV and the difference between exciting state (J=E¹) and ground state (J=Eº) for the hydrogen atom is in value of 0.059 meV. • The supply with a potential level of energy (Eº + 0.059 meV) to electrons of oxygen from water can increase the value of pH. In the excited state of trans-conformation molecule, it have been showed that the angle H-H from oxygen atom, becomes more large 108*grades, in comparison with those in ground state which has 105* grades. •
• • Because of electron redistribution from central Oxygen ion in water molecule H-O-H, the O‫½־‬ ion becomes with two ions of H more reached in energy and remains in state for more time, as a biological memory. • In the normal status, the molecules of water will pulse in liquid like a hart, with movement in the same plan,( twisting), and in out of plane ( rocking). The main changes of inter-atomic distance are also between the atoms of bridge fragment O-H. During of an excitation, the total length of distance between H and O atom increases with 0.3 A. The van der Waals forces action to distance of 2-3 A and depends of stearical energy (0.04* 10³ meV). • I water, designed photo-reactive molecules, which perform reaction, during energetic excitation is used as a molecule trigger for followed molecules of water. The network of molecular wires and molecular dynamic memory can be implemented into molecular nano-robots, composed from another molecule of different fluids. •
In reaction ADP³ + P2¯ + H2----ATP + H2O, and in reversible sense, terminal oxygen from ADP has draws the atom P2¯ with formation of intermediate penta- covalent length and than has place a dissociation of molecular complex in ATP and H2O. This reaction need of Mg participation and ATP-synthetase, known as comp;ex H+_ATP-ase or FoF1-ATP-ase, when FO=conductor proton and F1=ATP synthesized. In fact, the Mg and Ca participate to activation more than 300-400 enzymes which transfer group of phosphate in metabolic process and contribute to intermediate metabolism by degradation of molecular composes with high energy on aerobe way. The Mg2+ by high electronegativity of its electrons, stabilizes mitocondrial membrane in opposite with intracellular calcium which products mitochondrial swollen and the its damage by calcification. Mg2+ in generally interacts with substrates through inner coordination sphere, stabilizing anions or reactive intermediates, also including binding to ATP and activating the molecule through nucleophilic attack of oxygen atom. In either case, because Mg2+ is only rarely fully dehydrated, as ligand it is more important rather than the ion itself. The Lewis acidity of Mg2+ (pKa 11.4) is used to allow both hydrolysis and condensation reactions.
The importance of magnesium to proper cellular function can not be overstated. Deficiency of Mg in nutrients results in disease which affect the organism. In single-cells organisms such as bacteria and yeast, a low level of magnesium manifests in greatly reduced growth rates. Also, Mg has a role in sinthesys of immune-globulins. A deficiency of Mg can lead to Non-Hodgkin limphomas, Hodgkin Lymphoma or Lympho-sarcoma. The Mg2+ ion tends to bind only weakly to proteins (Ka ≤ 105) and this can be exploited by the cell to switch enzymatic activity on and of by changes in the local concentration of Mg2+. Although the concentration of free cytoplasmic Mg2+ is on the order of 1 mmol/L, the total Mg2+ content of animal cells is 30 mmol/L, in plants the content of leaf endodermal cells has been measured at values as high as 100 mmol/L (Stelzer et al., 1990), and is buffered in storage compartments.
The hydration shell of the Mg2+ ion has a very tightly bound inner shell of six water molecules and a relatively tightly bound second shell containing 12 – 14 water molecules (Markham et al., 2002). Thus recognition of the Mg2+ ion probably requires some mechanism to interact initially with the hydration shell of Mg2+, followed by a direct recognition/binding of the ion to the protein. Due to the strength of the inner sphere complexing between Mg2+ and any ligand, multiple simultaneous interactions, with the transport protein at this level, might significantly retard the ion in the transport by pore of membrane cells. Hence, it is possible that much of the hydration water is retained during transport, allowing action of in electrons carrier of Mg.
Was determined and crystal structures of the full-length protozoar Thermotoga maritima CorA, Mg protein transporter and its cytoplasmic domain at 3.9 A and 1.85 A resolution, respectively. The transporter is a funnel-shaped homo-pentamer protein chains with two trans-membrane helices per monomer. The cytoplasmic neck of the pore is surrounded, on the outside of the funnel, by a ring of highly conserved positively charged residues. Two negatively charged helices in the cytoplasmic domain extend back towards the membrane on the outside of the funnel and abut the ring of positive charge. An apparent Mg2+ ion was bound between monomers at a conserved site in the cytoplasmic domain, suggesting a mechanism to link gating of the pore, to the intracellular concentration of Mg2+. Figure 2
To date, the ZntA protein of protozoar Paramecium, Mg protein trasporter, has been shown to be a Mg2+ channel. The mechanisms of Mg2+ transport by the remaining proteins are beginning to be uncovered with the first three dimensional structure of a Mg2+ transport complex. Magnesium ions (Mg2+) in cellular biology are usually in almost all senses opposite to Ca2+ ions, because they are bivalent too, but have greater electronegativity and thus hold on to water molecules stronger, preventing passage through the channel of membrane. Thus Mg2+ ions block Ca2+ channels. Magnesium can affect muscle relaxation through direct action on the cell membrane. Mg++ ions close certain types of calcium channels, which conduct a positively charged calcium ion into the neuron. With an excess of magnesium, more channels will be blocked and the nerve will have less activity. Scheme 2
Traditional medicine along years has confirmed that red, orange and green vegetables, by reach content of Beta-oydants and Beta-alanina, Fe and Mg, (Example, Beetroot), have an anti-tumor activity, block development of cancer cells which have a predominant an-aerob metabolism and activate the system cyto-chrome oxidase enzyme, on aerobic away, increasing the speed of celullar breath from mithocondria, in “vivo” and in “vitro’. Some good sources of magnesium: Green vegetables such as spinach provide a high cantity of magnesium because of the abundance of chlorophyll molecules which contain the Mg ion. Nuts (especially almonds) and some whole grains are also good sources of magnesium. Figure 3 Too much magnesium may make it difficult for the body to absorb calcium. Not enough magnesium can lead to hypomagnesemia, manifested by irregular heart beats, high blood pressure (a sign in humans but not some experimental animals), insomnia and muscle spasms (fasciculation).
Figure 3 Space-filling model of the chlorophyll a molecule, with the Magnesium ion (bright green) visible at the center of the porphyrin group.
ROLE OF Mg to NUCLEIC ACIDS Nucleic acids have an important range of interactions with Mg2+. The binding of Mg2+ to DNA and RNA stabilizes its structure; this can be observed in the increased melting temperature (Tm) of double-stranded DNA in the presence of Mg2+. Additionally, ribosomes contain large amounts of Mg2+ and the stabilization by Mg ion is essential to the complex of ribo-proteins. A large number of enzymes is involved in the biochemistry of nucleic acids bind Mg2+, using the ion for its both activation and catalysis. Finally, the autocatalysis of many ribozymes (enzymes containing only RNA) is Mg2+ dependent. Biological membranes are impermeable to Mg2+ (and some other ions) so transport proteins must facilitate the flow of Mg2+, both into and out of cells and intracellular compartments.
Indeed, Mg2+-dependent enzymes appear in virtually every metabolic pathway: specific binding of Mg2+ to biological membranes is frequently observed, Mg2+ being also used as a signal molecule. In nucleotides, the triple phosphate moiety of the compound is invariably stabilized by association with Mg2+ in all enzymatic processes. Normally the body cells communicate by intra-cytoplasmic channel and energetic potential of membrane cells is 1-2.5 absolute value, as raport: ATP-ADP/ATP-ADP-IMP. In conditions of this range has place process of normal division of cells. If intracellular level of Mg is low, the extra-membrane charges of cells will by not uniformly distributed and a high positive extra-potential of cell will drive to loss of contact inhibition of cells, initiating the process of carcinogenesis by effect of elctromagnetic induction of oscillation, from central malign cells, the molecules from around malign cells be charged with the same high positive electric potential, as an energetic tranfer between cells and will be initiated the aberrant processes of high proteins and enzymes synthesis, characteristically cancer cells. High level of energy from anaerobic ATP, in 100 time values more than in normal cells, correspond to a very high membrane potential, carcateriscaly with high rate of divisions cells
SCHEME 3
Biophys J. 2010 Mar 3;98(5):784-92. FIGURE 5
CONCLUSIONS: The mechanisms of Mg2+ transport by the remaining proteins are beginning to be uncovered with the first three dimensional structure of a Mg2+ transport complex, recent discovered. Figure 4 Natural compounds of Mg can be used in bio-technology to manufacture of dugs, in conventional classic medicine, in naturist medicine, in homeopath medicine and in laboratories of molecular biology, in the experiments for to increase life span of stem cells, cultivated on a specific biological culture medium

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Mg Atp

  • 1. Role of Ion Mg as Cofactor ATP in Assurance of Energetic Environment Cells Aurelian Udristioiu, Clinical Laboratory, Medical Analyses Emergency County Hospital Targu Jiu
  • 2. Magnesium is an essential element in biological systems. Magnesium occurs typically as the Mg2+ ion. It is an essential mineral nutrient for life and is present in every cell type in every organism. For example, ATP (adenosine triphosphate), the main source of energy in cells, must be bound to a magnesium ion in order to be biologically active. What is called ATP is often actually Mg-ATP. Mg to Cell membranes Biological cell membranes and cell walls are poly- anionic surfaces. This has important implications for the transport of ions, particularly because it has been shown that different membranes preferentially bind different ions. Both Mg2+ and Ca2+ regularly stabilize membranes by the cross-linking of carboxylated and phosphorylated head groups of lipids.
  • 3. The transport of ions is dependent on both the concentration gradient of the ion and the electric potential (ΔΨ) across the membrane, which will be affected by the charge on the membrane surface. The entry of Mg2+ into cells may occur through one of two pathways, via channels using the ΔΨ (negative inside) across this membrane or by support with H+ ions. A schematic of a plant cell is shown including the four major compartments currently recognition as interacting with Mg2+, H+- ATPases maintains a constant ΔpH across the plasma membrane and the vacuole membrane. Mg2+ is transported into the vacuole using the energy of ΔpH. The transport of Mg2+ into mitochondria probably uses ΔΨ and it is likely with chloroplasts which take Mg2+ by a similar system. Magnesium ions can be critical in maintaining the positional integrity of closely clustered phosphate groups. These clusters appear in numerous and distinct parts of the cell nucleus and cytoplasm. Figure 1
  • 4. Figure 1: Magnesium in the plant cell
  • 5. Mg and ANAEROBIC METABOLISM in CYTOPLASM OF CELLS In all alive bodies immediated energy sources there are process of oxidation of glucose. In biochemical processes of Anaerobic. Metabolism, the donor of phosphate group is ATP and the reaction is catalyzed of the enzymes hexokinase or glucokinase. hexokinase Glucose +ATP=Glucose-6-phosphate Mg (DGo = -3.4kal/mol). The process of transformation of glucose-6-phosphate in fructose-6- phosphate is catalyzed by enzyme phospho-glucomutase, having as and co-factor ATP+Mg. In fellow step,transformation G-6-phosphate in F-1-6-biphophate, under the action of enzyme phosphofructokinase, reactant is ATP-Mg, and the reaction have place with decrease of free energy, being un-reversible in cellular normal conditions in sequence of glicolitc degradation.
  • 6. In twice steady of glicolyse, the acid phopho-enolpiruvic, in present of Mg²+ and K+ is transformed in piruvic acid. In cancer cells or in absence of oxygen have place the transformation piruvic acid in lactic acid and the glicolyse stop here. The energetic sum of anaerobic-glicolyse is total DG0 = -34.64 kcal/mol but the molecule of glucose contain 686 kcal/mol and the difference (-654 .51 kcal ) can remains a potential for un-controlled reactions in carcinogenesis. Lack of Mg in one of reaction of anaerobic glicolyse, can block the transformation of anaerobic process in aerobic process and the carcinogenetic process will be installed on via pentozo-phosphate away( G-6-P + NADPH+ - RIBOZA – 5 –P + CO2 + NAPHH+ 2H+). The pentose way is a strategic steps for malign cell with multiple syntheses of nucleic acids, without ATP consume, in build of purine bases necessary in build of sequences of AND.
  • 7. CITOPLASM CELLS-AEROBIC METABOLISM In Aerobic Glucose Metabolism, acid citric oxidation is helped of ADP and Mg²+ increases speed of reaction: Iso-citric acid + NADP (NAD) ---isocitrat-dehidrogenase = alpha-ceto-glutaric acid. Finally, in a health cell, will be delivery -299.06 kcal(71.54 KJ), minim level of energy for alive cells being 60 KJ, corresponding to a potential membrane of +- 60-90 mEv, the difference from 654.51 kcal will be lost by reversible reactions. Role of ATP-Mg to Mitocondryal Level To level of mitochondria the gradient of pH and potential membrane means “motrice force” of proton which is necessary in ATP synthesis from Krebs cycle. The concentration of H+ become high in place of mitocondrial cytosolic and a electric potential is born in this place. This proton of “ motric force”, of 0.22 mEv, correspond to a level of free energy de 5.2 Kcal/ proton molecule. The transfer of electron from NADPH in each every place of conserved energy transmit conformational exchanges of mitocondrial enzymes. Scheme 1. Graphic 1
  • 9.
  • 10. • Changes in pH value into fluids of cells can occur because inversion of electron spin, to hydrogen atoms, with increase of energy to electrophil oxygen atom from H2O molecules, becoming trigger for levogir vibrational molecules, as the estimation: H-O-H>>H-O-H±. • The energy of parallel spin at electron from fundamental position (unexciting) will be increased to anti-parallel position spin (exciting) in value of 0.04*10³ meV. The energy of oscillation for hydrogen atom is in water is in value of 0.04*10_5 meV and the difference between exciting state (J=E¹) and ground state (J=Eº) for the hydrogen atom is in value of 0.059 meV. • The supply with a potential level of energy (Eº + 0.059 meV) to electrons of oxygen from water can increase the value of pH. In the excited state of trans-conformation molecule, it have been showed that the angle H-H from oxygen atom, becomes more large 108*grades, in comparison with those in ground state which has 105* grades. •
  • 11. • • Because of electron redistribution from central Oxygen ion in water molecule H-O-H, the O‫½־‬ ion becomes with two ions of H more reached in energy and remains in state for more time, as a biological memory. • In the normal status, the molecules of water will pulse in liquid like a hart, with movement in the same plan,( twisting), and in out of plane ( rocking). The main changes of inter-atomic distance are also between the atoms of bridge fragment O-H. During of an excitation, the total length of distance between H and O atom increases with 0.3 A. The van der Waals forces action to distance of 2-3 A and depends of stearical energy (0.04* 10³ meV). • I water, designed photo-reactive molecules, which perform reaction, during energetic excitation is used as a molecule trigger for followed molecules of water. The network of molecular wires and molecular dynamic memory can be implemented into molecular nano-robots, composed from another molecule of different fluids. •
  • 12. In reaction ADP³ + P2¯ + H2----ATP + H2O, and in reversible sense, terminal oxygen from ADP has draws the atom P2¯ with formation of intermediate penta- covalent length and than has place a dissociation of molecular complex in ATP and H2O. This reaction need of Mg participation and ATP-synthetase, known as comp;ex H+_ATP-ase or FoF1-ATP-ase, when FO=conductor proton and F1=ATP synthesized. In fact, the Mg and Ca participate to activation more than 300-400 enzymes which transfer group of phosphate in metabolic process and contribute to intermediate metabolism by degradation of molecular composes with high energy on aerobe way. The Mg2+ by high electronegativity of its electrons, stabilizes mitocondrial membrane in opposite with intracellular calcium which products mitochondrial swollen and the its damage by calcification. Mg2+ in generally interacts with substrates through inner coordination sphere, stabilizing anions or reactive intermediates, also including binding to ATP and activating the molecule through nucleophilic attack of oxygen atom. In either case, because Mg2+ is only rarely fully dehydrated, as ligand it is more important rather than the ion itself. The Lewis acidity of Mg2+ (pKa 11.4) is used to allow both hydrolysis and condensation reactions.
  • 13. The importance of magnesium to proper cellular function can not be overstated. Deficiency of Mg in nutrients results in disease which affect the organism. In single-cells organisms such as bacteria and yeast, a low level of magnesium manifests in greatly reduced growth rates. Also, Mg has a role in sinthesys of immune-globulins. A deficiency of Mg can lead to Non-Hodgkin limphomas, Hodgkin Lymphoma or Lympho-sarcoma. The Mg2+ ion tends to bind only weakly to proteins (Ka ≤ 105) and this can be exploited by the cell to switch enzymatic activity on and of by changes in the local concentration of Mg2+. Although the concentration of free cytoplasmic Mg2+ is on the order of 1 mmol/L, the total Mg2+ content of animal cells is 30 mmol/L, in plants the content of leaf endodermal cells has been measured at values as high as 100 mmol/L (Stelzer et al., 1990), and is buffered in storage compartments.
  • 14. The hydration shell of the Mg2+ ion has a very tightly bound inner shell of six water molecules and a relatively tightly bound second shell containing 12 – 14 water molecules (Markham et al., 2002). Thus recognition of the Mg2+ ion probably requires some mechanism to interact initially with the hydration shell of Mg2+, followed by a direct recognition/binding of the ion to the protein. Due to the strength of the inner sphere complexing between Mg2+ and any ligand, multiple simultaneous interactions, with the transport protein at this level, might significantly retard the ion in the transport by pore of membrane cells. Hence, it is possible that much of the hydration water is retained during transport, allowing action of in electrons carrier of Mg.
  • 15. Was determined and crystal structures of the full-length protozoar Thermotoga maritima CorA, Mg protein transporter and its cytoplasmic domain at 3.9 A and 1.85 A resolution, respectively. The transporter is a funnel-shaped homo-pentamer protein chains with two trans-membrane helices per monomer. The cytoplasmic neck of the pore is surrounded, on the outside of the funnel, by a ring of highly conserved positively charged residues. Two negatively charged helices in the cytoplasmic domain extend back towards the membrane on the outside of the funnel and abut the ring of positive charge. An apparent Mg2+ ion was bound between monomers at a conserved site in the cytoplasmic domain, suggesting a mechanism to link gating of the pore, to the intracellular concentration of Mg2+. Figure 2
  • 16.
  • 17. To date, the ZntA protein of protozoar Paramecium, Mg protein trasporter, has been shown to be a Mg2+ channel. The mechanisms of Mg2+ transport by the remaining proteins are beginning to be uncovered with the first three dimensional structure of a Mg2+ transport complex. Magnesium ions (Mg2+) in cellular biology are usually in almost all senses opposite to Ca2+ ions, because they are bivalent too, but have greater electronegativity and thus hold on to water molecules stronger, preventing passage through the channel of membrane. Thus Mg2+ ions block Ca2+ channels. Magnesium can affect muscle relaxation through direct action on the cell membrane. Mg++ ions close certain types of calcium channels, which conduct a positively charged calcium ion into the neuron. With an excess of magnesium, more channels will be blocked and the nerve will have less activity. Scheme 2
  • 18.
  • 19. Traditional medicine along years has confirmed that red, orange and green vegetables, by reach content of Beta-oydants and Beta-alanina, Fe and Mg, (Example, Beetroot), have an anti-tumor activity, block development of cancer cells which have a predominant an-aerob metabolism and activate the system cyto-chrome oxidase enzyme, on aerobic away, increasing the speed of celullar breath from mithocondria, in “vivo” and in “vitro’. Some good sources of magnesium: Green vegetables such as spinach provide a high cantity of magnesium because of the abundance of chlorophyll molecules which contain the Mg ion. Nuts (especially almonds) and some whole grains are also good sources of magnesium. Figure 3 Too much magnesium may make it difficult for the body to absorb calcium. Not enough magnesium can lead to hypomagnesemia, manifested by irregular heart beats, high blood pressure (a sign in humans but not some experimental animals), insomnia and muscle spasms (fasciculation).
  • 20. Figure 3 Space-filling model of the chlorophyll a molecule, with the Magnesium ion (bright green) visible at the center of the porphyrin group.
  • 21. ROLE OF Mg to NUCLEIC ACIDS Nucleic acids have an important range of interactions with Mg2+. The binding of Mg2+ to DNA and RNA stabilizes its structure; this can be observed in the increased melting temperature (Tm) of double-stranded DNA in the presence of Mg2+. Additionally, ribosomes contain large amounts of Mg2+ and the stabilization by Mg ion is essential to the complex of ribo-proteins. A large number of enzymes is involved in the biochemistry of nucleic acids bind Mg2+, using the ion for its both activation and catalysis. Finally, the autocatalysis of many ribozymes (enzymes containing only RNA) is Mg2+ dependent. Biological membranes are impermeable to Mg2+ (and some other ions) so transport proteins must facilitate the flow of Mg2+, both into and out of cells and intracellular compartments.
  • 22. Indeed, Mg2+-dependent enzymes appear in virtually every metabolic pathway: specific binding of Mg2+ to biological membranes is frequently observed, Mg2+ being also used as a signal molecule. In nucleotides, the triple phosphate moiety of the compound is invariably stabilized by association with Mg2+ in all enzymatic processes. Normally the body cells communicate by intra-cytoplasmic channel and energetic potential of membrane cells is 1-2.5 absolute value, as raport: ATP-ADP/ATP-ADP-IMP. In conditions of this range has place process of normal division of cells. If intracellular level of Mg is low, the extra-membrane charges of cells will by not uniformly distributed and a high positive extra-potential of cell will drive to loss of contact inhibition of cells, initiating the process of carcinogenesis by effect of elctromagnetic induction of oscillation, from central malign cells, the molecules from around malign cells be charged with the same high positive electric potential, as an energetic tranfer between cells and will be initiated the aberrant processes of high proteins and enzymes synthesis, characteristically cancer cells. High level of energy from anaerobic ATP, in 100 time values more than in normal cells, correspond to a very high membrane potential, carcateriscaly with high rate of divisions cells
  • 24. Biophys J. 2010 Mar 3;98(5):784-92. FIGURE 5
  • 25. CONCLUSIONS: The mechanisms of Mg2+ transport by the remaining proteins are beginning to be uncovered with the first three dimensional structure of a Mg2+ transport complex, recent discovered. Figure 4 Natural compounds of Mg can be used in bio-technology to manufacture of dugs, in conventional classic medicine, in naturist medicine, in homeopath medicine and in laboratories of molecular biology, in the experiments for to increase life span of stem cells, cultivated on a specific biological culture medium