High Activities of Glutamine Transaminase K (Dichlorovinylcysteine β‐Lyase) and ω‐Amidase in the Choroid Plexus of Rat Brain

Certain halogenated hydrocarbons, e.g., dichlo‐roacetylene, are nephrotoxic to experimental animals and neurotoxic to humans; cysteine‐S‐conjugate β‐lyases may play a role in the nephrotoxicity. We now show that with dichlorovinylcysteine as substrate the only detectable cysteine‐S‐conjugate β‐lyase in rat brain homogenates is identical to glutamine transaminase K. The predominant (mitochondrial) form of glutamine transaminase K in rat brain was shown to be immunologically distinct from the predominant (cytosolic) form of the enzyme in rat kidney. Glutamine transaminase K and ω‐amidase (constituents of the glutaminase II pathway) activities were shown to be widespread throughout the rat brain. However, the highest specific activities of these enzymes were found in the choroid plexus. The high activity of glutamine transaminase K in choroid plexus was also demonstrated by means of an immunohistochemical staining procedure. Glutamine transaminase K has a broad specificity toward amino acid and α‐keto acid substrates. The ω‐amidase also has a broad specificity; presumably, however, the natural substrates are α‐ketoglutaramate and α‐ketosuccinamate, the α‐keto acid analogues of glutamine and aspara‐gine, respectively. The high activities of both glutamine transaminase K and ω‐amidase in the choroid plexus suggest that the two enzymes are linked metabolically and perhaps are coordinately expressed in that organ. The data suggest that the natural substrate of glutamine transaminase K in rat brain is indeed glutamine and that the metabolism of glutamine through the glutaminase II pathway (i.e., l ‐glutamine and α‐keto acid α‐ketoglutarate and l ‐amino acid + ammonia) is an important function of the choroid plexus. Moreover, the present findings also suggest that any explanation of the neurotoxicity of halogenated xenobiotics must take into account the role of glutamine transaminase K and its presence in the choroid plexus.