Arg-52 in the Melibiose Carrier of Escherichia coli Is Important for Cation-Coupled Sugar Transport and Participates in an Intrahelical Salt Bridge

Arg-52 of the Escherichia coli melibiose carrier was replaced by Ser (R52S), Gln (R52Q), or Val (R52V). While the level of carrier in the membrane for each mutant remained similar to that for the wild type, analysis of melibiose transport showed an uncoupling of proton cotransport and a drastic reduction in Na(+)-coupled transport. Second-site revertants were selected on MacConkey plates containing melibiose, and substitutions were found at nine distinct locations in the carrier. Eight revertant substitutions were isolated from the R52S strain: Asp-19-->Gly, Asp-55-->Asn, Pro-60-->Gln, Trp-116-->Arg, Asn-244-->Ser, Ser-247-->Arg, Asn-248-->Lys, and Ile-352-->Val. Two revertants were also isolated from the R52V strain: Trp-116-->Arg and Thr-338-->Arg revertants. The R52Q strain yielded an Asp-55-->Asn substitution and a first-site revertant, Lys-52 (R52K). The R52K strain had transport properties similar to those of the wild type. Analysis of melibiose accumulation showed that proton-driven accumulation was still defective in the second-site revertant strains, and only the Trp-116-->Arg, Ser-247-->Arg, and Asn-248-->Lys revertants regained significant Na(+)-coupled accumulation. In general, downhill melibiose transport in the presence of Na(+) was better in the revertant strains than in the parental mutants. Three revertant strains, Asp-19-->Gly, Asp-55-->Asn, and Thr-338-->Arg strains, required a high Na(+) concentration (100 mM) for maximal activity. Kinetic measurements showed that the N248K and W116R revertants lowered the K(m) for melibiose, while other revertants restored transport velocity. We suggest that the insertion of positive charges on membrane helices is compensating for the loss of Arg-52 and that helix II is close to helix IV and VII. We also suggest that Arg-52 is salt bridged to Asp-55 (helix II) and Asp-19 (helix I).     

The interaction between aspartic acid 237 and lysine 358 in the lactose carrier of Escherichia coli.

The lacY from Escherichia coli strains 020 and AE43 have been cloned on plasmids which were designated p020-K358T and pAE43-D237N. These lacY mutants contain amino acid substitutions changing Lys-358 to Thr or Asp-237 to Asn, respectively. The charge neutralizing effect of each mutation is associated with a functional defect in melibiose transport which we exploited in order to isolate second site revertants to the melibiose-positive phenotype. Eleven melibiose-positive revertants of p020-K358T were isolated. All contained a second-site mutation converting Asp-237 to a neutral amino acid (8 to Asn, 1 to Gly, and 2 to Tyr). Twelve melibiose-positive revertants of pAE43-D237N were isolated. Two were second-site revertants converting Lys-358 to a neutrally Gln residue, while the remainder directly reverted Asn-237 to the wild-type Asp-237. We conclude that the functional intimate relationship between Asp-237 and Lys-358 suggests that these residues may be closely juxtaposed in three-dimensional space, possibly forming a 'charge-neutralizing' salt bridge.     

Asp-286----Asn-286 in polyomavirus large T antigen relaxes the specificity of binding to the polyomavirus origin.

We isolated revertants of a polyomavirus whose origin of DNA replication contains a point mutation in the palindrome to which large T antigen binds. Four independent second-site revertants contain an Asp-286----Asn-286 substitution in large T antigen. This mutant large T antigen activates replication of DNAs containing the mutant polyomavirus origin as well as replication of DNAs containing the wild-type origin; however, replication of DNAs with enhancer mutations is not activated by this large T antigen. The Asn-286 mutation occurs in a positively charge region of large T antigen near the location of several mutations which inactivate DNA replication. We suggest that this region of large T antigen is responsible for recognition of specific DNA sequences at the origin and that ionic forces are important for this interaction.     

Characterization of recombinant murine interleukin 5 expressed in Chinese hamster ovary cells.

We have purified recombinant murine interleukin 5 (rmIL-5) from the supernatant of Chinese hamster ovary cells. Each peptide fragment of the purified rmIL-5 generated by Achromobacter protease I digestion was characterized and glycosylation sites were determined. Although rmIL-5 contains three potential sites of N-linked glycosylation (Asn-26, Asn-55 and Asn-69), Asn-69 is not glycosylated. The oligosaccharides released from the protein by hydrazinolysis were fractionated by paper electrophoresis, lectin column chromatography and gel permeation chromatography, and their structures were analysed by sequential exoglycosidase digestion in combination with methylation analysis. The results indicated that they are a mixture of bi-, tri- and tetraantennary complex-type sugar chains with and without a fucose at the C-6 position of the proximal N-acetylglucosamine residue and high-mannose-type sugar chains. Although > 80% of the sugar chains are neutral oligosaccharides similar to recombinant human IL-5 (rhIL-5; Kodama, S., Endo, T., Tsuroka, N., Tsujimoto, M. and Kobata, A. (1991) J. Biochem., 110, 693-701), rmIL-5 has more tetraantennary oligosaccharides than rhIL-5. A site differential study revealed that Asn-55 has more tetraantennary oligosaccharides than Asn-26.     

Biochemical Characterization and Structural Analysis of a Bifunctional Cellulase/Xylanase from Clostridium thermocellum

We expressed an active form of CtCel5E (a bifunctional cellulase/xylanase from Clostridium thermocellum), performed biochemical characterization, and determined its apo- and ligand-bound crystal structures. From the structures, Asn-93, His-168, His-169, Asn-208, Trp-347, and Asn-349 were shown to provide hydrogen-bonding/hydrophobic interactions with both ligands. Compared with the structures of TmCel5A, a bifunctional cellulase/mannanase homolog from Thermotoga maritima, a flexible loop region in CtCel5E is the key for discriminating substrates. Moreover, site-directed mutagenesis data confirmed that His-168 is essential for xylanase activity, and His-169 is more important for xylanase activity, whereas Asn-93, Asn-208, Tyr-270, Trp-347, and Asn-349 are critical for both activities. In contrast, F267A improves enzyme activities.     

Heterodimerization of the two major envelope proteins is essential for arterivirus infectivity

The two major envelope proteins of arteriviruses, the membrane protein (M) and the major glycoprotein (GP(5)), associate into a disulfide-linked heterodimer that is incorporated into the virion and has been assumed to be a prerequisite for virus assembly. Using an equine arteritis virus (EAV) infectious cDNA clone, we have analyzed the requirement for GP(5)-M heterodimerization and have identified the Cys residues involved in the formation of the GP(5)-M disulfide bond. The single Cys residue (Cys-8) in the M ectodomain was crucial for heterodimerization and virus infectivity. Mutagenesis of any of the five Cys residues in the GP(5) ectodomain or removal of the single GP(5) N-glycosylation site also rendered the full-length clone noninfectious. However, an analysis of revertants yielded an exceptional pseudorevertant in which residues 52 to 79 of the GP(5) ectodomain had been deleted and the original Cys-80-->Ser mutation had been maintained. Consequently, this revertant lacked the GP(5) N-glycosyation site (Asn-56) and retained only a single cysteine residue (Cys-34). By using this GP(5) deletion, we confirmed that Cys-34 of GP(5) and Cys-8 of M are essential for GP(5)-M heterodimerization, a key event in the assembly of the EAV envelope.     

Agglutination and mating activity of the MF alpha 2-encoded alpha-factor analog in Saccharomyces cerevisiae.

The MF alpha 2-encoded Asn-5,Arg-7 alpha-factor-like peptide has been shown shown to have similar activity to Gln-5,Lys-7 alpha-factor in morphogenesis and growth arrest studies (S. Raths, P. Shenbagamurthi, F. Naider, and J. M. Becker, J. Bacteriol. 168:1468-1471, 1986). We tested the Asn-5,Arg-7 peptide in agglutination and mating assays and found that its activity was similar to or slightly less than that of the Gln-5,Lys-7 alpha-factor. The Asn-5,Arg-7 alpha-factor-like peptide is thus the most active analog of the Gln-5,Lys-7 alpha-factor known.     

UV-mutagenesis in Bacillus subtilis. IV. Analysis of revertants to methionine prototrophy]

UV light induces in Bacillus subtilis met5 ade6 two classes of revertants to prototrophy to methionine which can be easily distinguished by their phenotype: double (Met+Ade+) and solitary (Met+) revertants. Crosses of revertants with the wild type, carried out in transformational experiments, showed that original (direct) mutation met5 is presented in chromosome of double revertants. Consequently they are extragenic suppressor revertants. In the chromosome of solitary revertants Met+ an extragenic suppressor was not detected; reversions Met+ seem to be of an intragenic nature. It is possible to use reversions to prototrophy to methionine as a model to study UV-mutagenesis in suppressor and non-suppressor genes.     

Human cationic trypsinogen. Role of Asn-21 in zymogen activation and implications in hereditary pancreatitis

Mutation Asn-21 --> Ile in human cationic trypsinogen (Tg-1) has been associated with hereditary pancreatitis. Recent studies with rat anionic Tg (Tg-2) indicated that the analogous Thr-21 --> Ile mutation stabilizes the zymogen against autoactivation, whereas it has no effect on catalytic properties or autolytic stability of trypsin (Sahin-Tóth, M. (1999) J. Biol. Chem. 274, 29699-29704). In the present paper, human cationic Tg (Asn-21-Tg) and mutants Asn-21 --> Ile (Ile-21-Tg) and Asn-21 --> Thr (Thr-21-Tg) were expressed in Escherichia coli, and zymogen activation, zymogen degradation, and trypsin autolysis were studied. Enterokinase activated Asn-21-Tg approximately 2-fold better than Ile-21-Tg or Thr-21-Tg, and catalytic parameters of trypsins were comparable. At 37 degrees C, in 5 mm Ca(2+), all three trypsins were highly stable. In the absence of Ca(2+), Asn-21- and Ile-21-trypsins suffered autolysis in an indistinguishable manner, whereas Thr-21-trypsin exhibited significantly increased stability. In sharp contrast to observations with the rat proenzyme, at pH 8.0, 37 degrees C, autoactivation kinetics of Asn-21-Tg and Ile-21-Tg were identical; however, at pH 5. 0, Ile-21-Tg autoactivated at an enhanced rate relative to Asn-21-Tg. Remarkably, at both pH values, Thr-21-Tg showed markedly higher autoactivation rates than the two other zymogens. Finally, autocatalytic proteolysis of human zymogens was limited to cleavage at Arg-117, and no digestion at Lys-188 was detected. The observations indicate that zymogen stabilization by Ile-21 as observed in rat Tg-2 is not characteristic of human Tg-1. Instead, an increased propensity to autoactivation under acidic conditions might be relevant to the pathomechanism of the Asn-21 --> Ile mutation in hereditary pancreatitis. In the same context, faster autoactivation and increased trypsin stability caused by the Asn-21 --> Thr mutation in human Tg-1 might provide a rationale for the evolutionary divergence from Thr-21 found in other mammalian trypsinogens.     

Evidence that the asparagine 322 mutant of the lactose permease transports protons and lactose with a normal stoichiometry and accumulates lactose against a concentration gradient.

The single asparagine 322 mutant of the lactose permease was made by constructing a hybrid plasmid which contained the amino-terminal coding sequence from the wild-type permease gene and the carboxyl-terminal coding sequence from a previously characterized double mutant permease which contained an asparagine residue at position 322. Since histidine at position 322 has been postulated to be critically involved with H+ transport and the active accumulation of sugars, the ability of the Asn-322 mutant to couple H+ and sugar transport was carefully examined. Measurements of proton/lactose stoichiometries gave very similar values for the wild-type (0.78) and the Asn-322 strain (0.82). Moreover, the Asn-322 mutant was able to effectively accumulate lactose against a concentration gradient although the levels of accumulation in the Asn-322 mutant (approximately 5-7-fold) were significantly less than that of the wild-type strain (approximately 30-40-fold). Overall, these results are inconsistent with the notion that an ionizable histidine residue at position 322 is obligatorily required for H+ transport or the active accumulation of galactosides against a concentration gradient. The ability of the Asn-322 mutant to recognize a variety of sugars was compared with wild-type, Val-177, and Val-177/Asn-322 strains. The Asn-322 mutant exhibited an ability to recognize and transport maltose (an alpha-glucoside) which was significantly better than the wild-type strain but not as good as either the single Val-177 mutant or the double Val-177/Asn-322 mutant. Both the Asn-322 and the Val-177/Asn-322 strain showed a relatively poor recognition for alpha-galactosides (i.e. melibiose), beta-galactosides (lactose and thiodigalactoside), and beta-glucosides (cellobiose). In contrast, the single Val-177 strain exhibited a normal recognition for these sugars.     

Modeling,Substrate Docking,and Mutational Analysis Identify Residues Essential for the Function and Specificity of a Eukaryotic Purine-Cytosine NCS1 Transporter

The recent elucidation of crystal structures of a bacterial member of the NCS1 family, the Mhp1 benzyl-hydantoin permease from Microbacterium liquefaciens, allowed us to construct and validate a three-dimensional model of the Aspergillus nidulans purine-cytosine/H⁺ FcyB symporter. The model consists of 12 transmembrane α-helical, segments (TMSs) and cytoplasmic N- and C-tails. A distinct core of 10 TMSs is made of two intertwined inverted repeats (TMS1–5 and TMS6–10) that are followed by two additional TMSs. TMS1, TMS3, TMS6, and TMS8 form an open cavity that is predicted to host the substrate binding site. Based on primary sequence alignment, three-dimensional topology, and substrate docking, we identified five residues as potentially essential for substrate binding in FcyB; Ser-85 (TMS1), Trp-159, Asn-163 (TMS3), Trp-259 (TMS6), and Asn-354 (TMS8). To validate the role of these and other putatively critical residues, we performed a systematic functional analysis of relevant mutants. We show that the proposed substrate binding residues, plus Asn-350, Asn-351, and Pro-353 are irreplaceable for FcyB function. Among these residues, Ser-85, Asn-163, Asn-350, Asn-351, and Asn-354 are critical for determining the substrate binding affinity and/or the specificity of FcyB. Our results suggest that Ser-85, Asn-163, and Asn-354 directly interact with substrates, Trp-159 and Trp-259 stabilize binding through π-π stacking interactions, and Pro-353 affects the local architecture of substrate binding site, whereas Asn-350 and Asn-351 probably affect substrate binding indirectly. Our work is the first systematic approach to address structure-function-specificity relationships in a eukaryotic member of NCS1 family by combining genetic and computational approaches.     

Biological activity of the Asn-5,Arg-7 tridecapeptide encoded by MF alpha 2 of Saccharomyces cerevisiae.

The precursor predicted by the nucleotide sequence of the MF alpha 2 gene of Saccharomyces cerevisiae contains one copy of the tridecapeptide alpha-factor previously characterized (H2N-Trp-His-Trp-Leu-Gln-Leu-Lys-Pro-Gly-Gln-Pro-Met-Tyr-COOH) and one copy of a peptide that contains two conservative amino acid substitutions (H2N-Trp-His-Trp-Leu-Asn-Leu-Arg-Pro-Gly-Gln-Pro-Met-Tyr-COOH). To determine whether the novel molecule possesses biological activity, the Asn-5,Arg-7 tridecapeptide was prepared chemically by solid-phase peptide synthesis. Growth arrest and morphogenesis assays gave identical activity profiles for the Asn-5,Arg-7 peptide and the other gene product, the Gln-5,Lys-7 peptide. The activities of the two peptides were additive and indistinguishable for S. cerevisiae X2180-1A. When present in fourfold molar excess, the biologically inactive desTrp-1,Ala-3 dodecapeptide reversed activity of the Asn-5,Arg-7 and Gln-5,Lys-7 tridecapeptides. Furthermore, neither peptide caused growth arrest of a MATa ste2(Ts) mutant when assayed at the restrictive temperature. These studies suggest that both pheromones interact with the alpha-factor receptor in a similar manner.     

Molecular-mass heterogeneity of Griffonia simplicifolia lectin IV subunits. Differences in the oligosaccharide moieties in the N-terminal region.

Lectin IV of Griffonia simplicifolia (Mr approximately 56,000), which has a strong affinity for both the Lewis b and Y blood-group determinants, is a dimeric protein of two subunits, alpha (29 kDa) and beta (27 kDa), separable by SDS/PAGE and containing covalently linked oligosaccharide. After digestion with N-glycanase, the protein migrates as a single band with a mobility identical with that of the beta-subunit. After cleavage with hydroxylamine of 3H-labelled, but otherwise intact, lectin, the radioactively labelled oligosaccharide was found to be associated with two blocked N-terminal peptides separable by h.p.l.c. and having identical amino acid compositions. One of these had three or four glucosamine residues per molecule, whereas the other had only one or two. Sequence analyses of these, as well as of a 21 kDa hydroxylamine-cleaved fragment and of the intact lectin pretreated with pyroglutamate aminopeptidase, have provided a unique sequence for residues 1-62 of the two subunits. Evidence is presented for two sites of N-linked oligosaccharide attachment at Asn-5 and Asn-18. Whereas the alpha-subunit has oligosaccharide linked to both sites, the beta-subunit has carbohydrate associated with only one (Asn-18). Sugar analyses of the whole lectin reveal a monosaccharide composition of (Xyl)3(Fuc)2(Man)10(GlcNAc)6, representing 6.4% of the mass of the molecule. Taken together with the susceptibility of the Asn-5 linkage (but not of Asn-18) to N-glycanase digestion, the observations indicate that the structures of the oligosaccharides at residues 5 and 18 are different.     

Structures of sugar chains of ricin D

The toxic lectin, ricin D, contains mannose, fucose, xylose, and N-acetylglucosamine as sugar components. Sugar chains are linked to Asn-10 of the A-chain, and to Asn-95 and Asn-135 of the B-chain (Funatsu, G. et al. (1978) Agric. Biol. Chem. 42, 501-503; Araki, T. & Funatsu, G. (1985) FEBS Lett. 191, 121-124). Asparagine-linked sugar chains of each glycopeptide from ricin D were liberated by hydrazinolysis followed by N-acetylation. The reducing end residues of the sugar chains were coupled with 2-aminopyridine and the pyridylamino (PA-) derivatives obtained were purified by gel-filtration and reversed-phase HPLC. Eight main PA-sugar chains were obtained from three glycopeptides and the structures of these sugar chains were determined by component analysis, stepwise exoglycosidase digestions, partial acetolysis, and 500 MHz 1H-NMR spectroscopy. The results show that oligomannose type sugar chains (Man6-7GlcNAc2) are linked to Asn-95; Man5-7 GlcNAc2 and M4X (structure, see below) to Asn-135 of the B-chain, and M3FX and M3X to Asn-10 of the A-chain. (Formula: see text).     

An essential oligomannosidic glycan chain in the catalytic domain of autotaxin, a secreted lysophospholipase-D

Autotaxin/NPP2, a secreted lysophospholipase-D, promotes cell proliferation, survival, and motility by generating the signaling molecule lysophosphatidic acid. Here we show that ectonucleotide pyrophosphatase/phosphodiesterase 2 (NPP2) is N-glycosylated on Asn-53, Asn-410, and Asn-524. Mutagenesis and deglycosylation experiments revealed that only the glycosylation of Asn-524 is essential for the expression of the catalytic and motility-stimulating activities of NPP2. The N-glycan on Asn-524 was identified as Man8/9GlcNAc2, which is rarely present on mature eukaryotic glycoproteins. Additional studies show that this Asn-524-linked glycan is not accessible to alpha-1,2-mannosidase, suggesting that its non-reducing termini are buried inside the folded protein. Consistent with a structural role for the Asn-524-linked glycan, only the mutation of Asn-524 augmented the sensitivity of NPP2 to proteolysis and increased its mobility during Blue Native PAGE. Asn-524 is phylogenetically conserved and maps to the catalytic domain of NPP2, but a structural model of this domain suggests that Asn-524 is remote from the catalytic site. Our study defines an essential role for the Asn-524-linked glycan chain of NPP2.     

Protease domain glycans affect oligomerization, disulfide bond formation, and stability of the meprin A metalloprotease homo-oligomer

The meprin A homo-oligomer is a highly glycosylated, secreted zinc metalloprotease of the astacin family and metzincin superfamily. This isoform of meprin is composed of disulfide-bonded dimers of alpha subunits that further associate to form large, secreted megadalton complexes of 10 or more subunits. The aim of this study was to determine the sites of glycan attachment and to assess their ability to affect the formation and stability of the homo-oligomer. Nine of the ten potential N-linked glycosylation sites (Asn-41, Asn-152, Asn-234, Asn-270, Asn-330, Asn-426, Asn-452, Asn-546, and Asn-553) were found to be glycosylated in recombinant mouse meprin A using chemical and enzymatic deglycosylation methods and electrospray ionization mass spectrometry. Chemical cross-linking demonstrated that carbohydrates are at or near the noncovalent subunit interface. The removal of two glycans in the protease domain at Asn-234 and Asn-270, as well as one in the tumor necrosis factor receptor-associated factor domain at Asn-452, by a deglycosidase under nondenaturing conditions decreased the chemical and thermal stability of the homo-oligomer without affecting quaternary structure. Site-directed mutagenesis demonstrated that no single glycan was essential for oligomer formation; however, the combined absence of the glycans at Asn-152 and Asn-270 in the protease domain hindered intersubunit disulfide bond formation, prevented noncovalent associations, and abolished enzymatic activity. These studies provide insights into the role of glycans in the biosynthesis, activity, and stability of this extracellular protease.     

Human serum IgM glycosylation: identification of glycoforms that can bind to mannan-binding lectin

The glycoprotein IgM is the major antibody produced in the primary immune response to antigens, circulating in the serum both as a pentamer and a hexamer. Pentameric IgM has a single J chain, which is absent in the hexamer. The mu (heavy) chain of IgM has five N-linked glycosylation sites. Asn-171, Asn-332, and Asn-395 are occupied by complex glycans, whereas Asn-402 and Asn-563 are occupied by oligomannose glycans. The glycosylation of human polyclonal IgM from serum has been analyzed. IgM was found to contain 23.4% oligomannose glycans GlcNAc2Man5-9, consistent with 100% occupancy of Asn-402 and 17% occupancy of the variably occupied site at Asn-563. Mannan-binding lectin (MBL) is a member of the collectin family of proteins, which bind to oligomannose and GlcNAc-terminating structures. A commercial affinity chromatography resin containing immobilized MBL has been reported to be useful for partial purification of mouse and also human IgM. Human IgM glycoforms that bind to immobilized MBL were isolated; these accounted for only 20% of total serum IgM. Compared with total serum IgM, the MBL-binding glycoforms contained 97% more GlcNAc-terminating structures and 8% more oligomannose structures. A glycosylated model of pentameric IgM was constructed, and from this model, it became evident that IgM has two distinct faces, only one of which can bind to antigen, as the J chain projects from the non-antigen-binding face. Antigen-bound IgM does not bind to MBL, as the target glycans appear to become inaccessible once IgM has bound antigen. Antigen-bound IgM pentamers therefore do not activate complement via the lectin pathway, but MBL might have a role in the clearance of aggregated IgM.     

Frequency of spontaneous mutations in an avian hepadnavirus infection

In this study, we measured the frequency of revertants of a cytopathic strain of the duck hepatitis B virus that bears a single nucleotide substitution in the pre-S envelope protein open reading frame, resulting in the amino acid substitution G133E. Cytopathic virus mixed with known amounts of a genetically marked wild-type virus was injected into ducklings. Virus outgrowth was accompanied by a coselection of wild-type and spontaneous revertants during recovery of the ducklings from the acute liver injury caused by death of the G133E-infected cells. The frequency of individual revertants in the selected noncytopathic virus population was estimated by determining the ratio of each revertant to the wild-type virus. Spontaneous revertants were found to be present at frequencies of 1 x 10(-5) to 6 x 10(-5) per G133E genome inoculated. A mathematical model was used to estimate that the mutation rate was 0.8 x 10(-5) to 4.5 x 10(-5) per nucleotide per generation.     

Short-term treatment with gamma interferon induces stable reversion of ras-transformed mouse fibroblasts.

Persistent revertants have been generated from NIH 3T3 cells transformed by an activated human Ha-ras gene after short-term gamma interferon treatment in the presence of the cardiac aminoglycoside ouabain. Normal fibroblastlike morphology and anchorage dependence are restored in revertants. Tumorigenicity in nude mice is abolished. The revertants continue to express high steady-state levels of the ras oncogene. Partial retransformation of reverted cells is induced after 5-azacytidine treatment or after infection with retrovirus vectors carrying the v-abl, v-fes, v-myc, or v-src oncogene. The revertants resist the transforming activities of the v-Ha-ras and v-mos oncogenes.     

Imprecise excision of the Caenorhabditis elegans transposon Tc1 creates functional 5' splice sites.

Imprecise excision of the Caenorhabditis elegans transposon Tc1 from a specific site of insertion within the unc-54 myosin heavy chain gene generates either wild-type or partial phenotypic revertants. Wild-type revertants and one class of partial revertants contain insertions of four nucleotides in the unc-54 third exon (Tc1 "footprints"). Such revertants express large amounts of functional unc-54 myosin despite having what would appear to be frameshifting insertions in the unc-54 third exon. We demonstrate that these Tc1 footprints act as efficient 5' splice sites for removal of the unc-54 third intron. Splicing of these new 5' splice sites to the normal third intron splice acceptor removes the Tc1 footprint from the mature mRNA and restores the normal translational reading frame. Partial revertant unc-54(r661), which contains a single nucleotide substitution relative to the wild-type gene, is spliced similarly, except that the use of its new 5' splice site creates a frameshift in the mature mRNA rather than removing one. In all of these revertants, two alternative 5' splice sites are available to remove intron 3. We determined the relative efficiency with which each alternative 5' splice site is used by stabilizing frameshifted mRNAs with smg(-) genetic backgrounds. In all cases, the upstream member of the two alternative sites is used preferentially (> 75% utilization). This may reflect an inherent preference of the splicing machinery for the upstream member of two closely spaced 5' splice sites. Creation of new 5' splice sites may be a general characteristic of Tc1 insertion and excision events.