Go toArchive
Browse byFacets
Bookbag ( 0 )
'Phosphate Homeostasis' in keywords
Results  2 Items
Sorted by   
Section
Publication Year
1989 (1)
1988 (1)
1Author    F.C M Driessens, R.M H Verbeeck, J.W E Van Dijk, J.M P M BorggrevenRequires cookie*
 Title    Degree of Saturation of Blood Plasma in Vertebrates with Octocalcium Phosphate  
 Abstract    In previous papers it has been shown that octocalcium phospate OCP occurs in bone mineral of vertebrates. Although this compound is not stable, there is a continuous new-formation of OCP due to bone turnover. Literature data of the calcium and phosphate concentrations in the blood plasma of vertebrates were collected and the degree of saturation with OCP was calculated. The results show that blood plasma of vertebrates is almost saturated with OCP. This fact indicates that OCP is the solubility controlling phase in the mineral of vertebrates. Further it verifies the expectation based on physicochemical theory that the interaction between body fluids and bone mineral is important in the calcium and phosphate homeostasis. 
  Reference    Z. Naturforsch. 43c, 74—76 (1988); received April 23/November 2 1987 
  Published    1988 
  Keywords    Calcium Homeostasis, Phosphate Homeostasis, Vertebrates 
  Similar Items    Find
 DEBUG INFO      
 TEI-XML for    default:Reihe_C/43/ZNC-1988-43c-0074.pdf 
 Identifier    ZNC-1988-43c-0074 
 Volume    43 
2Author    U. H. Eber, J. Viil, S. Neimanis, T. Mimura, K.-J DietzRequires cookie*
 Title    Photoinhibitory Damage to Chloroplasts under Phosphate Deficiency and Alleviation of Deficiency and Damage by Photorespiratory Reactions  
 Abstract    D edicated to P rofessor A chim Trebst on the occasion o f his 60th birthday Effects of Pi deficiency on photosynthesis ot isolated spinach chloroplasts were examined. The following observations were made: (1) Chloroplasts isolated in Pi-free media evolved oxygen in the light in the absence of added Pi until acid-extractable P, in the chloroplasts had decreased to 1 to 2.5 m M . This Pj was unavailable for photophosphorylation as shown by the inability of the chloroplasts to respond by oxygen evolution to the addition of PGA. In the state of Prdeficiency, stromal ATP to A DP ratios were in the light close to or below ratios observed in the dark. In the presence of 2 mM PGA, addition of 20 (j.m Pi was insufficient to increase ATP to ADP ratios, but sufficient for appreciable oxygen evolution. (2) More Pi was available for oxygen evolution of phosphate-deficient chloroplasts at low levels of C 0 2 than at high levels. This was due mainly to the suppression of oxygenation of RuBP by high C 0 2 levels which prevented formation of phosphoglycolate and the subsequent release of Pi into the chloroplast stroma. (3) More oxygen was produced by phosphate-deficient chloroplasts at a low light intensity than at a high light intensity. This was due to increased availability of endogenous Pi under low light and to photoinhibition of the chloroplasts by high light. The main product of photosynthesis of phosphate-deficient chloroplasts in the presence of a high bicarbonate concentration was starch, and the main soluble product was PGA. (4) After phosphate-deficient chloroplasts had ceased to evolve oxygen in the light, they be­ came photosensitive. Part of the loss of the capacity for oxygen evolution is attributed to leakage of PGA, but the main reason for loss of function is photoinactivation of electron transport. Both photosystems of the electron transport chain were damaged by light. (5) Protection against photoinactivation was provided by coupled electron transport. Photo­ inactivation of phosphate-deficient chloroplasts was less extensive in the presence of low C 0 2 concentrations which permitted oxygenation of RuBP than at high CO: concentrations. Electron transport to C 0 2 and other physiological electron acceptors and to the herbicide methylviologen was also protective. However, electron transport to oxygen in the Mehler reaction failed to provide appreciable protection against high light intensities, because oxygen reduction is slow and reactive oxygen species produced in the light contribute to photoinactivation. 
  Reference    Z. Naturforsch. 44c, 524 (1989); received February 3 1989 
  Published    1989 
  Keywords    Photosynthesis, Photoinhibition, Photorespiration, Electron Transport, Phosphate Deficiency, Phosphate Homeostasis 
  Similar Items    Find
 DEBUG INFO      
 TEI-XML for    default:Reihe_C/44/ZNC-1989-44c-0524.pdf 
 Identifier    ZNC-1989-44c-0524 
 Volume    44