Advertisement
Translational Research
Advanced searchSave search
Research Article| Volume 81, ISSUE 1, P37-42, January 1973

Fatty acid biosynthesis in the erythrocyte. II. Evidence in immature erythrocytes for the presence of acetyl co-enzyme A carboxylase

DOI:https://doi.org/10.5555/uri:pii:0022214373902692
Fatty acid biosynthesis in the erythrocyte. II. Evidence in immature erythrocytes for the presence of acetyl co-enzyme A carboxylase
Previous ArticleQuantitative relationships of the pituitary-gonadal axis in postmenopausal women
Next ArticleIncreased activity of two enzymes of pyrimidine biosynthesis de novo in erythrocytes from patients with the Lesch-Nyhan syndrome
      This paper is only available as a PDF. To read, Please Download here.

      Abstract

      Rabbit erythrocytes rich in reticulocytes are able to synthesize long-chain fatty acids from either acetate or acetyl coenzyme A. This is due to the presence of the enzyme acetyl coenzyme A carboxylase, which is absent in the mature erythrocyte. This enzymatic activity can be shown to fall to zero as the erythrocyte population matures. In common with other tissues, acetyl coenzyme A carboxylase in immature erythrocytes is a biotin enzyme system and requires ATP, HCO3, and Mn++; and is stimulated by acids of the tricarboxylic acid cycle. Preliminary evidence is also presented suggesting the presence of this enzyme in an erythrocyte extract of a patient with a high reticulocyte count.
      To read this article in full you will need to make a payment

      Purchase one-time access:

      Academic & Personal: 24 hour online accessCorporate R&D Professionals: 24 hour online access
      One-time access price info
      • For academic or personal research use, select 'Academic and Personal'
      • For corporate R&D use, select 'Corporate R&D Professionals'

      Subscribe:

      Subscribe to Translational Research
      Already a print subscriber? Claim online access
      Already an online subscriber? Sign in
      Register: Create an account
      Institutional Access: Sign in to ScienceDirect

      References

        • Majerus PW
        • Vagelos PR
        Fatty acid biosynthesis and the role of acyl carrier protein.
        Adv Lipid Res. 1967; 5: 1
        • Vagelos PR
        Lipid metabolism.
        Ann Rev Biochem. 1967; 33: 139
        • Zakim D
        • Herman RK
        Regulation of fatty acid synthesis.
        Am J Clin Nutr. 1969; 22: 200
        • Martin DB
        • Vagelos PR
        Fatty acid synthesis in adipose tissue.
        in: Adipose Tissue. Handbook of Physiology. 1965: 211 (Section 5)
        • Kleinschmidt AK
        • Moss J
        • Lane MD
        Acetyl coenzyme A carboxylase: Filamentous nature of the animal enzymes.
        Science. 1969; 166: 1276
        • Alberts AW
        • Nervi AM
        • Vagelos PR
        Acetyl CoA carboxylase, II. Demonstration of biotin-protein and biotin carboxylase subunits.
        in: Proc Nat Acad Sci. 63. 1969: 1319
        • Martin DB
        • Vagelos PR
        The mechanism of tricarboxylic acid cycle regulation of fatty acid synthesis.
        J Biol Chem. 1962; 237: 1787
        • Waite M
        • Wakil SJ
        Studies on the mechanism of fatty acid synthesis. XII. Acetyl CoA carboxylase.
        J Biol Chem. 1962; 237: 2750
        • Kallen RG
        • Lowenstein JM
        The stimulation of fatty acid synthesis by isocitrate and malonate.
        Arch Biochem. 1962; 96: 188
        • Numa S
        • Matsuhashi M
        • Lynen F
        Zur storing der Fettsaure Synthese bei Hunger und Alloxandiabetis. I. Fettsaures Synthese in der leber normaler und hungernder Ratten.
        Biochem Z. 1961; 334: 203
        • Gibson DM
        • Hubbard DD
        Incorporation of malonyl CoA into fatty acids by liver in starvation and alloxan-diabetes.
        Biochem Biophys Res Commun. 1960; 3: 531
        • Korchak HM
        • Masoro EJ
        Changes in the level of fatty acid synthesizing enzymes during starvation.
        Biochim Biophys Acta. 1962; 58: 354
        • Vagelos RP
        • Majerus RW
        • Alberts AW
        • et al.
        Structure and function of the acyl carrier protein.
        in: Fed Proc. 25. 1966: 1485
        • Marks PA
        • Gellhorn A
        • Kidson C
        Lipid synthesis in human leukocytes, platelets, and erythrocytes.
        J Biol Chem. 1960; 235: 2579
        • O'Donnell VJ
        • Ottolenghi P
        • Malkin A
        • et al.
        The biosynthesis from acetate-1-C14 of fatty acids and cholesterol in formed blood elements.
        Can J Biochem. 1958; 36: 1125
        • Majerus PW
        • Lastra RR
        Fatty acid biosynthesis in human leukocytes.
        J Clin Invest. 1967; 46: 1596
        • Pittman JG
        • Martin DB
        Fatty acid biosynthesis in human erythrocytes: evidence in mature erythrocytes for an incomplete long-chain fatty acid synthesizing system.
        J Clin Invest. 1966; 45: 165
        • Simon EH
        • Shemin D
        The preparation of s-succinyl coenzyme A.
        J Am Chem Soc. 1953; 75: 2520
        • Trams EG
        • Brady RO
        The synthesis of malonyl-C14 coenzyme A.
        J Am Chem Soc. 1960; 82: 2972
        • Borsook H
        • Deasy CL
        • Kaagen-Smit AJ
        • et al.
        Incorporation in vitro of labeled amino acids into proteins of rabbit reticulocytes.
        J Biol Chem. 1952; 196: 669
        • Skoog WA
        • Beck WS
        Studies on the fibrinogen, dextran, and phytohemagglutin methods of isolating leukocytes.
        Blood. 1956; 11: 436
        • Warburg O
        • Christian W
        Isolierund und Kristallisation des garungsferments Enolase.
        Biochem Z. 1941–1943; 310: 384
        • Ganguly J
        Studies on the mechanism of fatty acid synthesis. VII. Biosynthesis of fatty acids from malonyl CoA.
        Biochim Biophys Acta. 1960; 40: 110
        • Martin DB
        • Horning MG
        • Vagelos PR
        Fatty acid synthesis in adipose tissue. I. Purification and properties of a long-chain fatty acid synthesizing system.
        J Biol Chem. 1961; 236: 663
        • Chapman RG
        • Schaumburg L
        Glycolysis and glycolytic enzyme activity of aging red cells in man.
        Br J Haemat. 1967; 13: 665
        • Rubinstein D
        • Ottolenghi P
        • Denstedt OF
        The metabolism of the erythrocytes. XIII. Enzyme activity in the reticulocyte.
        Can J Biochem Physiol. 1956; 34: 222
        • Prankerd TAJ
        Aging of red cells.
        J Physiol. 1958; 143: 325
        • Cooper RA
        Lipids of human red cell membrane: Normal composition and variability in disease.
        in: Semin Hematol. 7. 1970: 296

      Article info

      Publication history

      Accepted: September 29, 1972
      Received: June 21, 1972

      Footnotes

      Supported by Grants from National Institutes of Health No AM13774-02 and AM05205-12, National Science Foundation No. BO19636, and Research Grants from the American Diabetes Association and the John Hartford Foundation.

      Identification

      DOI: https://doi.org/10.5555/uri:pii:0022214373902692

      Copyright

      © 1973 Published by Elsevier Inc.

      ScienceDirect

      Access this article on ScienceDirect

      The content on this site is intended for healthcare professionals.


      We use cookies to help provide and enhance our service and tailor content. To update your cookie settings, please visit the Cookie Preference Center for this site.
      Copyright © 2023 Elsevier Inc. except certain content provided by third parties.


      RELX