A novel nonopioid action of enkephalins: competitive inhibition of the mammalian brain high affinity L-proline transporter.

The high affinity L-proline transporter (PROT) is a member of the family of Na+ (and Cl-)-dependent plasma membrane transport proteins that comprises transporters for several neurotransmitters, osmolytes, and metabolites. The brain-specific expression of PROT in a subset of putative glutamatergic pathways implies a specialized function for this novel transporter and its presumed natural substrate L-proline in excitatory synaptic transmission. However, definitive studies of the physiological role(s) of high affinity L-proline uptake have been precluded by the lack of specific uptake inhibitors. Here, we report that Leu- and Met-enkephalin and their des-tyrosyl derivatives potently and selectively inhibited high affinity L-proline uptake in rat hippocampal synaptosomes and in PROT-transfected HeLa cells. High concentrations of the opiate receptor antagonist naltrexone did not block the inhibitory actions of these peptides, arguing against an involvement of opioid receptors. Des-tyrosyl-Leu-enkephalin elevated the apparent K(m) of L-proline transport in transfected HeLa cells without altering the V(max). PROT-transfected HeLa cells did not accumulate [3H]Leu-enkephalin above background levels, demonstrating that enkephalins are not substrates for PROT. These findings indicate that enkephalins competitively inhibit mammalian brain PROT through a direct interaction with the transporter protein at or near the L-proline binding site. The high potency and specificity of des-tyrosyl-Leu-enkephalin make this compound a useful tool for elucidating the structure-function properties and physiological role(s) of PROT.

Human brain-specific L-proline transporter: molecular cloning, functional expression, and chromosomal localization of the gene in human and mouse genomes.

L-Proline fulfills several of the classic criteria used to identify amino acid neurotransmitters, including the presence of a high affinity, Na(+)- (and Cl-)-dependent synaptosomal transport process and the Ca(2+)-dependent release of exogenously loaded radiolabeled L-proline from brain slices and synaptosomes after K(+)-induced depolarization. However, studies to define the role of L-proline in discrete pathways in the mammalian brain have been precluded by the inability to block its biosynthesis or high affinity transport in nervous tissue. We report the molecular cloning, functional expression, and chromosomal localization of a human brain-specific high affinity L-proline transporter (hPROT). The pharmacological specificity, kinetic properties, and ionic requirements of hPROT clearly distinguish this carrier from the other Na(+)-dependent plasma membrane carriers that transport L-proline. Multiple tissue Northern blot analysis revealed a prominent approximately 4-kb mRNA transcript in human brain tissue, whereas no specific hybridizing species were detected in peripheral tissue. An antipeptide antiserum directed against the carboxy-terminus of the predicted hPROT protein identified a single, broad immunoreactive protein of 68 kDa on immunoblots of synaptosomal membranes from various human brain regions. In contrast, no specific labeling was detected on immunoblots of membranes from human liver, kidney, or heart. A differential distribution of hPROT mRNA and protein was observed in the human corpus striatum, consistent with the hypothesis that the hPROT protein is synthesized in neuronal cell bodies in an extrastriatal location and axonally transported to the corpus striatum. These findings warrant the consideration of a synaptic regulatory role for this transporter and its presumed natural substrate, L-proline, in the mammalian central nervous system.

Mammalian brain-specific L-proline transporter. Neuronal localization of mRNA and enrichment of transporter protein in synaptic plasma membranes.

The expression of a high affinity Na(+)- (and Cl-) dependent L-proline transporter (PROT) in subpopulations of putative glutamatergic pathways in rat brain raises the possibility of a specific physiological role(s) for this carrier in excitatory neurotransmission (Fremeau, R. T., Jr., Caron, M. G., and Blakely, R. D. (1992) Neuron 8, 915-926). However, the biochemical properties and regional, cellular, and subcellular distribution of the PROT protein have yet to be elucidated. Here, we document the brain-specific expression and neuronal localization of rat PROT mRNA. We also report the first identification and partial biochemical characterization of the mammalian brain PROT protein. An affinity-purified antipeptide antibody was produced that specifically recognized a single 68-kDa PROT protein on immunoblots of rat and human brain tissues. Deglycosylation of rat hippocampal membranes with peptide-N-glycosidase F reduced the apparent molecular mass of the native PROT protein from 68 to 53 kDa, the size of the primary PROT translation product determined by in vitro translation of the rat PROT cDNA in the absence of microsomes. Subcellular fractionation studies demonstrated that the PROT protein was enriched in synaptic plasma membranes but absent from postsynaptic densities. A differential distribution of PROT mRNA and protein was observed in rat striatum, suggesting that the transporter protein is synthesized in neuronal cell bodies in the cortex and exported to axon terminals in the caudate putamen. These findings warrant the consideration of a novel presynaptic regulatory role for this transporter in excitatory synaptic transmission.