Augmentation of the ascending component of the peristaltic reflex and substance P release by glial cell line-derived neurotrophic factor.

BACKGROUND: Glial cell line-derived neurotrophic factor (GDNF) is present in adult gut although its role in the mature enteric nervous system is not well defined. The aim of the present study was to examine the role of GDNF as neuromodulator of the ascending phase of the peristaltic reflex. METHODS: Colonic segments were prepared as flat sheets and placed in compartmented chambers so as to separate the sensory and motor limbs of the reflex. Ascending contraction was measured in the orad compartment and mucosal stroking stimuli (two to eight strokes) were applied in the caudad compartment. GDNF and substance P (SP) release were measured and the effects of GDNF and GDNF antibody on contraction and release were determined. Mice with reduced levels of GDNF (Gdnf(+/-)) and wild type littermates were also examined. KEY RESULTS: GDNF was released in a stimulus-dependent manner into the orad motor but not caudad sensory compartment. Addition of GDNF to the orad motor but not caudad sensory compartment augmented ascending contraction and SP release. Conversely, addition of GDNF antibody to the orad motor but not caudad sensory compartment reduced ascending contraction and SP release. Similarly, the ascending contraction and SP release into the orad motor compartment was reduced in Gdnf(+/-) mice as compared to wild type littermates. CONCLUSIONS & INFERENCES: The results suggest that endogenous GDNF is released during the ascending contraction component of the peristaltic reflex where it acts as a neuromodulator to augment SP release from motor neurons thereby augmenting contraction of circular muscle orad to the site of stimulation.

Neurturin signalling via GFRalpha2 is essential for innervation of glandular but not muscle targets of sacral parasympathetic ganglion neurons.

Neurturin, a member of the glial cell-derived neurotrophic factor familys of ligands, is important for development of many cranial parasympathetic ganglion neurons. We have investigated the sacral component of the parasympathetic nervous system in mice with gene deletions for neurturin or its preferred receptor, GFRalpha2. Disruption of neurturin signalling decreased cholinergic VIP innervation to the mucosa of the reproductive organs, but not to the smooth muscle layers of these organs or to the urinary bladder. Thus, neurturin and its receptor are involved in parasympathetic innervation of a select group of pelvic visceral tissues. In contrast, noradrenergic innervation was not affected by the gene ablations. The epithelium of reproductive organs from knockout animals was atrophied, indicating that cholinergic innervation may be important for the maintenance of normal structure. Cholinergic neurons express GFRalpha2 on their terminals and somata, indicating they can respond to neurotrophic support, and their somata are smaller when neurturin signalling is disrupted. Colocalisation studies showed that many peripheral glia express GFRalpha2 although its role in these cells is yet to be determined. Our results indicate that neurturin, acting through GFRalpha2, is essential for parasympathetic innervation of the mucosae of reproductive organs, as well as for maintenance of a broader group of sacral parasympathetic neurons.

RET signaling is essential for migration, axonal growth and axon guidance of developing sympathetic neurons.

Sympathetic axons use blood vessels as an intermediate path to reach their final target tissues. The initial contact between differentiating sympathetic neurons and blood vessels occurs following the primary sympathetic chain formation, where precursors of sympathetic neurons migrate and project axons along or toward blood vessels. We demonstrate that, in Ret-deficient mice, neuronal precursors throughout the entire sympathetic nervous system fail to migrate and project axons properly. These primary deficits lead to mis-routing of sympathetic nerve trunks and accelerated cell death of sympathetic neurons later in development. Artemin is expressed in blood vessels during periods of early sympathetic differentiation, and can promote and attract axonal growth of the sympathetic ganglion in vitro. This analysis identifies RET and artemin as central regulators of early sympathetic innervation.

Development of cranial parasympathetic ganglia requires sequential actions of GDNF and neurturin.

The neurotrophic factors that influence the development and function of the parasympathetic branch of the autonomic nervous system are obscure. Recently, neurturin has been found to provide trophic support to neurons of the cranial parasympathetic ganglion. Here we show that GDNF signaling via the RET/GFR(alpha)1 complex is crucial for the development of cranial parasympathetic ganglia including the submandibular, sphenopalatine and otic ganglia. GDNF is required early for proliferation and/or migration of the neuronal precursors for the sphenopalatine and otic ganglia. Neurturin exerts its effect later and is required for further development and maintenance of these neurons. This switch in ligand dependency during development is at least partly governed by the altered expression of GFR(&agr;) receptors, as evidenced by the predominant expression of GFR(&agr;)2 in these neurons after ganglion formation.

Anomalous development of the hepatobiliary system in the Inv mouse.

Extrahepatic biliary atresia (BA) is a devastating disease of the neonate in which the hepatic and/or common bile duct is obliterated or interrupted. Infants and children with this diagnosis constitute 50% to 60% of the pediatric population that undergoes orthotopic liver transplantation. However, there is still very little known about the etiology and pathogenesis of BA. Several recent studies have demonstrated that anomalies of situs determination are more commonly associated with BA than previously recognized. In this study, we examined the pathogenesis of jaundice in the inv mouse, a transgenic mouse in which a recessive deletion of the inversin gene results in situs inversus and jaundice. The results show that these mice have cholestasis with conjugated hyperbilirubinemia, failure to excrete technetium-labeled mebrofenin from the liver into the small intestine, lack of continuity between the extrahepatic biliary tree and the small intestine as demonstrated by Trypan blue cholangiography, and a liver histological picture indicative of extrahepatic biliary obstruction with negligible inflammation/necrosis within the hepatic parenchyma. Lectin histochemical staining of biliary epithelial cells in serial sections suggests the presence of several different anomalies in the architecture of the extrahepatic biliary system. These results suggest that the inversin gene plays an essential role in the morphogenesis of the hepatobiliary system and raise the possibility that alterations in the human orthologue of inversin account for some of the cases of BA in which there are also anomalies of situs determination.

Gene targeting reveals a critical role for neurturin in the development and maintenance of enteric, sensory, and parasympathetic neurons.

Neurturin (NTN) is a neuronal survival factor that activates the Ret tyrosine kinase in the presence of a GPI-linked coreceptor (either GFR alpha1 or GFR alpha2). Neurturin-deficient (NTN-/-) mice generated by homologous recombination are viable and fertile but have defects in the enteric nervous system, including reduced myenteric plexus innervation density and reduced gastrointestinal motility. Parasympathetic innervation of the lacrimal and submandibular salivary gland is dramatically reduced in NTN-/- mice, indicating that Neurturin is a neurotrophic factor for parasympathetic neurons. GFR alpha2-expressing cells in the trigeminal and dorsal root ganglia are also depleted in NTN-/- mice. The loss of GFR alpha2-expressing neurons, in conjunction with earlier studies, provides strong support for GFR alpha2/Ret receptor complexes as the critical mediators of NTN function in vivo.

GFR alpha1-deficient mice have deficits in the enteric nervous system and kidneys.

Glial cell line-derived neurotrophic factor (GDNF) signals through a receptor complex composed of the Ret tyrosine kinase and a glycosylphosphatidylinositol- (GPI-) anchored cell surface coreceptor, either GDNF family receptor alpha1 (GFR alpha1) or GFR alpha2. To investigate the usage of these coreceptors for GDNF signaling in vivo, gene targeting was used to produce mice lacking the GFR alpha1 coreceptor. GFR alpha1-deficient mice demonstrate absence of enteric neurons and agenesis of the kidney, characteristics that are reminiscent of both GDNF- and Ret-deficient mice. Midbrain dopaminergic and motor neurons in GFR alpha1 null mice were normal. Minimal or no neuronal losses were observed in a number of peripheral ganglia examined, including the superior cervical and nodose, which are severely affected in both Ret- and GDNF-deficient mice. These results suggest that while stringent physiologic pairing exists between GFR alpha1 and GDNF in renal and enteric nervous system development, significant cross-talk between GDNF and other GFR alpha coreceptors must occur in other neuronal populations.

Neurturin and GDNF promote proliferation and survival of enteric neuron and glial progenitors in vitro.

Signaling through the c-Ret tyrosine kinase and the endothelin B receptor pathways is known to be critical for development of the enteric nervous system. To clarify the role of these receptors in enteric nervous system development, the effect of ligands for these receptors was examined on rat enteric neuron precursors in fully defined medium in primary culture. In this culture system, dividing Ret-positive cells differentiate, cluster into ganglia containing neurons and enteric glia, and create extensive networks reminiscent of the enteric plexus established in vivo. Glial cell-line-derived neurotrophic factor (GDNF) and neurturin both potently support survival and proliferation of enteric neuron precursors in this system. Addition of either neurturin or GDNF to these cultures increased the number of both neurons and enteric glia. Persephin, a third GDNF family member, shares many properties with neurturin and GDNF in the central nervous system and in kidney development. By contrast, persephin does not promote enteric neuron precursor proliferation or survival in these cultures. Endothelin-3 also does not increase the number of enteric neurons or glia in these cultures.

Persephin, a novel neurotrophic factor related to GDNF and neurturin.

A novel neurotrophic factor named Persephin that is approximately 40% identical to glial cell line-derived neurotrophic factor (GDNF) and neurturin (NTN) has been identified using degenerate PCR. Persephin, like GDNF and NTN, promotes the survival of ventral midbrain dopaminergic neurons in culture and prevents their degeneration after 6-hydroxydopamine treatment in vivo. Persephin also supports the survival of motor neurons in culture and in vivo after sciatic nerve axotomy and, like GDNF, promotes ureteric bud branching. However, in contrast to GDNF and NTN, persephin does not support any of the peripheral neurons that were examined. Fibroblasts transfected with Ret and one of the coreceptors GFRalpha-1 or GFRalpha-2 do not respond to persephin, suggesting that persephin utilizes additional, or different, receptor components than GDNF and NTN.

Neurturin, a novel neurotrophic factor, is localized to mouse chromosome 17 and human chromosome 19p13.3.

Neurturin is a potent neurotrophic factor closely related to glial cell line-derived neurotrophic factor (GDNF, 40% amino acid sequence identity) and, like GDNF, can promote the survival of numerous neuronal populations including sympathetic, nodose, and dorsal root ganglion sensory neurons. Both neurturin and GDNF signal through the Ret tyrosine kinase and require a glycosylphosphatidylinositol-linked coreceptor. Mutations in Ret and GDNF cause intestinal aganglionosis and renal dysplasia. Activating Ret mutations also cause multiple endocrine neoplasia syndromes (MEN2A and MEN2B). We have isolated mouse and human genomic neurturin clones. The sequence for preproneurturin is encoded by two exons. Mouse and human clones have common intron/exon boundaries. We have used interspecific backcross analysis to localize neurturin to mouse chromosome 17 near the Vav locus and fluorescence in situ hybridization analysis to localize human neurturin to the syntenic region of human chromosome 19p13.3.

Neurturin shares receptors and signal transduction pathways with glial cell line-derived neurotrophic factor in sympathetic neurons.

Neurturin (NTN) is a neurotrophic factor that shares homology with glial cell line-derived neurotrophic factor (GDNF). Recently, a receptor complex has been identified for GDNF that includes the Ret tyrosine kinase receptor and a glycosylphosphatidylinositol-linked protein termed "GDNFRalpha." However, differences in the phenotype of Ret and GDNF knockout animals suggest that Ret has at least one additional ligand. In this report, we demonstrate that NTN induces Ret phosphorylation in primary cultures of rat superior cervical ganglion (SCG) neurons. NTN also caused Ret phosphorylation in fibroblasts that were transfected stably with Ret and GDNFRalpha but not in cells expressing Ret alone. A glycosylphosphatidylinositol-linked protein also was important for NTN and GDNF signaling in SCG neurons; phosphatidylinositol-specific phospholipase C treatment of SCG cultures reduced the ability of NTN to phosphorylate Ret and the ability of NTN or GDNF to activate the mitogen-activated protein kinase pathway. NTN and GDNF also caused sustained activation of Ret and the mitogen-activated protein kinase pathway in SCG neurons. Finally, both NTN and GDNF activated the phosphatidylinositol 3-kinase pathway in SCG neurons, which may be important for the ability of NTN and GDNF to promote neuronal survival. These data indicate that NTN is a physiologically relevant ligand for the Ret receptor and suggest that NTN may have a critical role in the development of many neuronal populations.

TrnR2, a novel receptor that mediates neurturin and GDNF signaling through Ret.

Glial cell line-derived neurotrophic factor (GDNF) and neurturin (NTN) comprise a family of TGF-beta-related neurotrophic factors (TRNs), which have trophic influences on a variety of neuronal populations. A receptor complex comprised of TrnR1 (GDNFR alpha) and Ret was recently identified and found to be capable of mediating both GDNF and NTN signaling. We have identified a novel receptor based on homology to TrnR1, called TrnR2, that is 48% identical to TrnR1, and is located on the short arm of chromosome 8. TrnR2 is attached to the cell surface via a GPI-linkage, and can mediate both NTN and GDNF signaling through Ret in vitro. Fibroblasts expressing TrnR2 and Ret are approximately 30-fold more sensitive to NTN than to GDNF treatment, whereas those expressing TrnR1 and Ret respond equivalently to both factors, suggesting the TrnR2-Ret complex acts preferentially as a receptor for NTN. TrnR2 and Ret are expressed in neurons of the superior cervical and dorsal root ganglia, and in the adult brain. Comparative analysis of TrnR1, TrnR2, and Ret expression indicates that multiple receptor complexes, capable of mediating GDNF and NTN signaling, exist in vivo.

Neurturin, a relative of glial-cell-line-derived neurotrophic factor.

The normal development of the vertebrate nervous system entails the death of 30-70% of the neurons originally generated in most neuronal populations. This naturally occurring cell death is regulated by specific neurotrophic factors that promote neuronal survival and which are produced in limiting quantities by target cells, glial cells and neurons. These factors are also of potential utility as therapeutic agents for neurodegenerative diseases. Here we describe the purification and cloning of a new neurotrophic factor, identified on the basis of its ability to support the survival of sympathetic neurons in culture. This factor, neurturin, is structurally related to glial-cell-line-derived neurotrophic factor (GDNF). These factors can each activate the MAP kinase signalling pathway in cultured sympathetic neurons and support the survival of sympathetic neurons, as well as of sensory neurons of the nodose and dorsal root ganglia. Thus, neurturin and GDNF together now define a new family of neurotrophic factors.

Functional analysis of protein N-myristoylation: metabolic labeling studies using three oxygen-substituted analogs of myristic acid and cultured mammalian cells provide evidence for protein-sequence-specific incorporation and analog-specific redistribution.

Covalent attachment of myristic acid (C14:0) to the NH2-terminal glycine residue of a number of cellular, viral, and oncogene-encoded proteins is essential for full expression of their biological function. Substitution of oxygen for methylene groups in this fatty acid does not produce a significant change in chain length or stereochemistry but does result in a reduction in hydrophobicity. These heteroatom-containing analogs serve as alternative substrates for mammalian myristoyl-CoA:protein N-myristoyltransferase (EC 2.3.1.97) and offer the opportunity to explore structure/function relationships of myristate in N-myristoyl proteins. We have synthesized three tritiated analogs of myristate with oxygen substituted for methylene groups at C6, C11, and C13. Metabolic labeling studies were performed with these compounds and (i) a murine myocyte cell line (BC3H1), (ii) a rat fibroblast cell that produces p60v-src (3Xsrc), or (iii) NIH 3T3 cells that have been engineered to express a fusion protein consisting of an 11-residue myristoylation signal from the Rasheed sarcoma virus (RaSV) gag protein linked to c-Ha-ras with a Cys----Ser-186 mutation. This latter mutation prevents isoprenylation and palmitoylation of ras. Two-dimensional gel electrophoresis of membrane and soluble fractions prepared from cell lysates revealed different patterns of incorporation of the analogs into cellular N-myristoyl proteins (i.e., protein-sequence-specific incorporation). In addition, proteins were identified that underwent redistribution from membrane to soluble fractions after incorporating one but not another analog (analog-specific redistribution). Comparable studies using the model RaSV-ras chimeric protein also demonstrated analog-specific differences in incorporation, varying from approximately 25% of the total RaSV-ras chimeric protein with 5-octyloxypentanoate to greater than 50% with 12-methoxydodecanoate. Modification by this latter compound was so extensive that the amount of membrane-associated N-myristoylated protein was decreased. Incorporation of each of the analogs caused a dramatic redistribution to the soluble fraction, comparable to that seen when myristoylation was completely blocked by mutating the protein's site of myristate attachment (glycine) to an alanine residue. The demonstration that these analogs differ in the extent to which they are incorporated and in their ability to cause redistribution of any single protein suggests that they may also have sufficient selectivity to be of potential therapeutic value.

Novel fatty acyl substrates for myristoyl-CoA:protein N-myristoyl-transferase.

Myristoyl-CoA:protein N-myristoyltransferase (NMT) catalyzes the covalent attachment of myristic acid to the NH2-terminal Gly residues of a number of viral and cellular proteins. The remarkable specificity of this enzyme for myristoyl CoA observed in vivo appears to arise in large part from a cooperativity between NMT's acylCoA and peptide binding sites: the length of the acylCoA bound to NMT influences the interactions of peptide substrates with NMT. We have previously synthesized analogs of myristic acid with single oxygen or sulfur for methylene substitutions. These heteroatom substitutions produce significant reductions in acyl chain hydrophobicity without accompanying alterations in chain length or stereochemical restrictions. In vitro studies have shown that the CoA thioesters of these analogs are substrates for S. cerevisiae NMT and that the efficiency of their transfer to octapeptide substrates is peptide sequence-dependent. In vivo studies with cultured mammalian cells have confirmed that these fatty acid analogs are selectively incorporated into a subset of cellular N-myristoylproteins, that only a subset of analog-substituted proteins undergo redistribution from membrane to cytosolic fractions, and that these analogs can inhibit the replication of human immunodeficiency virus I and Moloney murine leukemia viruses--two retroviruses that depend upon N-myristoylation of their gag polyprotein precursors for assembly. We have now extended our analysis of NMT-acylCoA interactions by synthesizing additional analogs of myristic acid and testing them in a coupled in vitro assay system. Myristic acid analogs with two oxygen or two sulfur substitutions have hydrophobicities comparable to that of hexanoic acid and decanoic acid, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Protein N-myristoylation in Escherichia coli: reconstitution of a eukaryotic protein modification in bacteria.

Protein N-myristoylation refers to the covalent attachment of a myristoyl group (C14:0), via amide linkage, to the NH2-terminal glycine residue of certain cellular and viral proteins. Myristoyl-CoA:protein N-myristoyltransferase (NMT) catalyzes this cotranslational modification. We have developed a system for studying the substrate requirements and biological effects of protein N-myristoylation as well as NMT structure-activity relationships. Expression of the yeast NMT1 gene in Escherichia coli, a bacterium that has no endogenous NMT activity, results in production of the intact 53-kDa NMT polypeptide as well as a truncated polypeptide derived from proteolytic removal of its NH2-terminal 39 amino acids. Each E. coli-synthesized NMT species has fatty acid and peptide substrate specificities that are indistinguishable from those of NMT recovered from Saccharomyces cerevisiae, suggesting that the NH2-terminal domain of this enzyme is not required for its catalytic activity. By using a dual plasmid system, N-myristoylation of a mammalian protein was reconstituted in E. coli by simultaneous expression of the yeast NMT1 gene and a murine cDNA encoding the catalytic (C) subunit of cAMP-dependent protein kinase (PK-A). The fatty acid specificity of N-myristoylation was preserved in this system: [9,10(n)-3H]myristate but not [9,10(n)3H]palmitate was efficiently linked to Gly-1 of the C subunit. [13,14(n)-3H]10-Propoxydecanoic acid, a heteroatom-containing analog of myristic acid with reduced hydrophobicity but similar chain length, was an effective alternative substrate for NMT that also could be incorporated into the C subunit of PK-A. Such analogs have recently been shown to inhibit replication of certain retroviruses that depend upon linkage of a myristoyl group to their gag polyprotein precursors (e.g., the Pr55gag of human immunodeficiency virus type 1). A major advantage of the bacterial system over eukaryotic systems is the absence of endogenous NMT and substrates, providing a more straightforward way of preparing myristoylated, analog-substituted, and nonmyristoylated forms of a given protein for comparison of their structural and functional properties. The system should facilitate screening of enzyme inhibitors as well as alternative NMT fatty acid substrates for their ability to be incorporated into a specific target protein. Our experimental system may prove useful for recapitulating other eukaryotic protein modifications in E. coli so that structure-activity relationships of modifying enzymes and their substrates can be more readily assessed.

Replication of human immunodeficiency virus 1 and Moloney murine leukemia virus is inhibited by different heteroatom-containing analogs of myristic acid.

Myristoyl-CoA:protein N-myristoyltransferase (NMT; EC 2.3.1.97) catalyzes the cotranslational linkage of myristate to the N-terminal glycine residues of several cellular, viral, and oncoproteins. We have recently synthesized a series of sulfur- and oxygen-substituted analogs of myristic acid that are similar in length to the 14:0 fatty acid yet have hydrophobicities equivalent to dodecanoate or decanoate. Previous in vitro enzyme assays and metabolic labeling studies indicate that some of these analogs are excellent substrates for NMT and are incorporated into subsets of cellular N-myristoyl proteins. Their sequence-specific incorporation probably arises from cooperative interactions between the acyl CoA and peptide binding sites of NMT. The human immunodeficiency virus 1 (HIV-1) and Moloney murine leukemia virus (MoMLV) depend on myristoylation of gag polyprotein precursors for assembly. We have tested four analogs--12-methoxydodecanoic acid, 10-propoxydecanoic acid, 5-octyloxypentanoic acid, and 11-ethylthioundecanoic acid--for their ability to block replication of these retroviruses. All reduce HIV-1 replication when incubated with CD4+ H9 cells for 10 days at 10-100 microM. 12-Methoxydodecanoic acid is most effective, producing a concentration-dependent decrease in (i) reverse transcriptase activity (to levels that were 5-10% of control at 20-40 microM), (ii) p24 levels, and (iii) syncytia formation. This degree of inhibition of HIV-1 replication is equivalent to that seen with 5 microM 3'-azido-3'-deoxythymidine and is accomplished without apparent toxicity, as measured by cell viability, protein, and nucleic acid synthesis. 5-Octyloxypentanoic acid inhibits MoMLV assembly in a dose-dependent fashion without accompanying cellular toxicity, while 12-methoxydodecanoic acid has no effect. These data suggest that the use of cellular NMT activity to deliver analogs of myristate with altered physical-chemical properties to proteins that undergo this cotranslational modification may represent an effective anti-viral therapeutic strategy as well as a way to investigate the role of covalently bound fatty acid in viral assembly.

Altered membrane association of p60v-src and a murine 63-kDa N-myristoyl protein after incorporation of an oxygen-substituted analog of myristic acid.

A number of viral and cellular proteins contain covalently bound lipid. In a subset of these acyl proteins, the 14-carbon saturated fatty acid myristic acid is attached through an amide linkage to an NH2-terminal glycine residue. Myristoyl-CoA:protein N-myristoyltransferase (NMT) transfers the myristoyl moiety from myristoyl-CoA to these nascent proteins and is highly selective for fatty acid chain length. We have found that 10-(propoxy)decanoyl-CoA (11-oxymyristoyl-CoA), an analog of myristic acid with reduced hydrophobicity, acts as a substrate for NMT both in vitro and in vivo. Comparison of the in vitro kinetic properties of a number of synthetic octapeptide substrates of NMT using myristoyl-CoA or 11-oxymyristoyl-CoA indicated that there is an interaction between the acyl-CoA and peptide binding sites of this acyltransferase. Peptide catalytic efficiency with 11-oxymyristoyl-CoA was reduced relative to that with myristoyl-CoA, but the extent of the reduction varied widely among the octapeptides tested. These in vitro data accurately predicted that only a subset of myristoyl proteins synthesized in Saccharomyces cerevisiae and a murine myocyte-like cell line (BC3H1) would incorporate 11-oxy[3H]myristate. Substitution of the myristoyl moiety by the 11-oxymyristoyl moiety does not significantly affect the membrane association of most N-myristoyl proteins. However, for the tyrosine kinase p60v-src and a 63-kDa N-myristoyl protein in BC3H1 cells, analog incorporation results in marked redistribution from the membrane to the cytosolic fraction. These studies demonstrate the utility of heteroatom-containing analogs for analysis of the role of myristate in acyl protein targeting. The sequence-specific nature of analog incorporation and the protein-specific effects on membrane association suggests that these compounds may represent a useful class of antiviral and antitumor agents.

Disruption of the yeast N-myristoyl transferase gene causes recessive lethality.

The structural gene for N-myristoyl transferase (NMT1) has been cloned from the budding yeast Saccharomyces cerevisiae. The gene encodes a polypeptide of 455 amino acids (Mr = 52,837) that has no identifiable significant primary sequence homology with any protein in currently available databases. Overexpression of NMT activity was achieved by means of the yeast episomal plasmid YEp24 without obvious effects on growth kinetics, cell morphology, or acylprotein metabolic labeling patterns. Insertional mutagenesis of the NMT1 locus on yeast chromosome XII caused recessive lethality, indicating that this protein acyltransferase activity is necessary for vegetative cell growth.

Heteroatom-substituted fatty acid analogs as substrates for N-myristoyltransferase: an approach for studying both the enzymology and function of protein acylation.

Myristoyl-CoA:protein N-myristoyltransferase (NMT), the enzyme that transfers the myristoyl (14:0) moiety from myristoyl CoA thioester to nascent proteins, is remarkably specific for both peptide and fatty acyl CoA substrates. To investigate the interaction of NMT with fatty acyl CoA substrates, we have synthesized 10 oxygen- or sulfur-substituted fatty acid analogs. These analogs differ dramatically in hydrophobicity from naturally occurring fatty acids of similar length. As acylpeptides, sulfur-substituted myristic acid analogs migrate on reverse-phase HPLC like 11:0 or 12:0 fatty acids, while oxygen-substituted analogs migrate like 9:0 to 11:0 fatty acids. CoA thioesters of several of these analogs serve as good NMT substrates in vitro, implying that NMT selects fatty acyl substrates primarily on the basis of chain length rather than hydrophobicity. Myristelaidoyl (14:1, delta 9,10-trans) CoA is also a significantly better substrate than myristoleoyl (14:1, delta 9,10-cis) CoA. The fatty acyl group bound to NMT profoundly influences the rate of acylpeptide formation and the affinity of NMT for peptide substrates. However, the peptide substrate bound to NMT does not produce significant alterations in the enzyme's affinity for myristoyl CoA. In vitro characterization of these heteroatom substituted analogs suggests that they will be efficiently incorporated into proteins in vivo and may markedly alter acylprotein targeting and function.