Characterization of a beta-actinin-like protein in purified non-muscle cell membranes. Its activity on (Na+ + K+)-ATPase.

Treatment by EDTA of purified plasma membranes from MF2S cells (a variant of the murine plasmacytoma MOPC 173) solubilized proteins and increased by a 1000-fold the sensitivity of (Na+ + K+)-ATPase to ouabain. When added back with Ca2+ to treated plasma membranes, these EDTA-solubilized proteins restored the initial sensitivity of the enzyme to its inhibitor. We report the purification of a protein of Mr 32000, isolated from the EDTA-treated membrane supernatant. This protein was purified by a one-step procedure involving a preparative polyacrylamide gel electrophoresis without detergent. In the presence of Ca2+ it was able to restore the original sensitivity to ouabain of (Na+ + K+)-ATPase from EDTA-treated membrane. This protein was shown to be similar to the beta-actinin described by Maruyama by the following criteria: (1) molecular weight and amino acid composition; (2) cross-reactivity with their respective antisera; (3) in the presence of Ca2+ the same quantitative biological activity on ouabain sensitivity of the (Na+ + K+)-ATPase. A possible interaction between beta-actinin, calmodulin and membrane-bound (Na+ + K+)-ATPase is discussed.

Acetylcholinesterase genes in the nematode Caenorhabditis elegans.

Acetylcholinesterase (AChE, EC 3.1.1.7) is responsible for the termination of cholinergic nerve transmission. It is the target of organophosphates and carbamates, two types of chemical pesticides being used extensively in agriculture and veterinary medicine against insects and nematodes. Whereas there is usually one single gene encoding AChE in insects, nematodes are one of the rare phyla where multiple ace genes have been unambiguously identified. We have taken advantage of the nematode Caenorhabditis elegans model to identify the four genes encoding AChE in this species. Two genes, ace-1 and ace-2, encode two major AChEs with different pharmacological properties and tissue repartition: ace-1 is expressed in muscle cells and a few neurons, whereas ace-2 is mainly expressed in motoneurons. ace-3 represents a minor proportion of the total AChE activity and is expressed only in a few cells, but it is able to sustain double null mutants ace-1; ace-2. It is resistant to usual cholinesterase inhibitors. ace-4 was transcribed but the corresponding enzyme was not detected in vivo.

Four genes encode acetylcholinesterases in the nematodes Caenorhabditis elegans and Caenorhabditis briggsae. cDNA sequences, genomic structures, mutations and in vivo expression.

We report the full coding sequences and the genomic organization of the four genes encoding acetylcholinesterase (AChE) in Caenorhabditis elegans and Caenorhabditis briggsae, in relation to the properties of the encoded enzymes. ace-1 and ace-2, located on chromosome X and I, respectively, encode two AChEs (ACE-1 and ACE-2) that present 35% identity. The C-terminal end of ACE-1 is homologous to the C terminus of T subunits of vertebrate AChEs. ACE-1 oligomerizes into amphiphilic tetramers. ACE-2 has a hydrophobic C terminus of H type. It associates into glycolipid-anchored dimers. In C. elegans and C. briggsae, ace-3 and ace-4 are organized in tandem on chromosome II, with only 356 nt and 369 nt, respectively, between the stop codon of ace-4 (upstream gene) and the ATG of ace-3. ace-3 produces only 5 % of the total AChE activity. It encodes an H subunit that associates into dimers of glycolipid-anchored catalytic subunits, which are highly resistant to the usual AChE inhibitors, and which hydrolyze butyrylthiocholine faster than acetylthiocholine. ACE-4 is closer to ACE-3 (54 % identity) than to ACE-1 or ACE-2. The usual sequence FGESAG surrounding the active serine residue in cholinesterases is changed to FGQSAG in ace-4. ACE-4 was not detected by our current biochemical methods, although the gene is transcribed in vivo. However the level of ace-4 mRNAs is far lower than those of ace-1, ace-2 and ace-3. The ace-2, ace-3 and ace-4 transcripts were found to be trans-spliced by both SL1 and SL2, although these genes are not included in typical operons. The molecular bases of null mutations g72 (ace-2), p1304 and dc2 (ace-3) have been identified.

Structure and promoter activity of the 5' flanking region of ace-1, the gene encoding acetylcholinesterase of class A in Caenorhabditis elegans.

We report the structure and the functional activity of the promoter region of ace-1, the gene encoding acetylcholinesterase of class A in the nematode Caenorhabditis elegans. We found that ace-1 was trans -spliced to the SL1 spliced leader and that transcription was initiated at a cluster of multiple starts. There was neither a TATA nor a CAAT box at consensus distances from these starts. Interspecies sequence comparison of the 5' regions of ace-1 in C. elegans and in the related nematode Caenorhabditis briggsae identified four blocks of conserved sequences located within a sequence of 2.4 kilobases upstream from the initiator ATG. In vitro expression of CAT reporter genes in mammalian cells allowed the determination of a minimal promoter in the first 288 nucleotides. In phenotype rescue experiments in vivo, the ace-1 gene containing 2.4 kilobases of 5' flanking region of either C. elegans or C. briggsae was found to restore a coordinated mobility to the uncoordinated double mutants ace-1(-);ace-2(-)of C. elegans. This showed that the ace-1 promoter was contained in 2.4 kilobases of the 5' region, and indicated that cis -regulatory elements as well as coding sequences of ace-1 were functionally conserved between the two nematode species. The pattern of ace-1 expression was established through microinjection of Green Fluorescent Protein reporter gene constructs and showed a major mesodermal expression. Deletion analysis showed that two of the four blocks of conserved sequences act as tissue-specific activators. The distal block is a mesodermal enhancer responsible for the expression in body wall muscle cells, anal sphincter and vulval muscle cells. Another block of conserved sequence directs expression in pharyngeal muscle cells pm5 and three pairs of cephalic sensory neurons.

Characterization of a null mutation in ace-1, the gene encoding class A acetylcholinesterase in the nematode Caenorhabditis elegans.

Two genes (ace-1 and ace-2) encode two major classes (A and B) of acetylcholinesterase (AChE) in the nematode Caenorhabditis elegans. A null mutation in ace-1 (allele p1000) suppresses all acetylcholinesterase activity of class A. We have identified an opal mutation TGG (W99)-->TGA (Stop) as the only alteration in the mutated gene. This leads to a truncated protein (98 instead of 620 amino acids) with no enzymatic activity. The mutation also reduces the level of ace-1 transcripts to only 10% of that in wild-type animals. This most likely results from a destabilization of mRNA containing the nonsense message. In contrast, compensation of class B by class A AChE in the null mutant strain ace-2 takes place with unchanged ace-1 mRNA level and enzymatic activity similar to class A AChE.

Existence of four acetylcholinesterase genes in the nematodes Caenorhabditis elegans and Caenorhabditis briggsae.

Three genes, ace-1, ace-2 and ace-3, respectively located on chromosomes X, I and II, were reported to encode acetylcholinesterases (AChEs) of classes A, B and C in the nematode Caenorhabditis elegans. We have previously cloned and sequenced ace-1 in the two related species C. elegans and C. briggsae. We report here partial sequences of ace-2 (encoding class B) and of two other ace sequences located in close proximity on chromosome II in C. elegans and C. briggsae. These two sequences are provisionally named ace-x and ace-y, because it is not possible at the moment to establish which of these two genes corresponds to ace-3. Ace-x and ace-y are transcribed in vivo as shown by RT-PCR and they are likely to be included in a single operon.

Four acetylcholinesterase genes in the nematode Caenorhabditis elegans.

Whereas a single gene encodes acetylcholinesterase (AChE) in vertebrates and most insect species, four distinct genes have been cloned and characterized in the nematode Caenorhabditis elegans. We found that ace-1 (mapped to chromosome X) is prominently expressed in muscle cells whereas ace-2 (located on chromosome I) is mainly expressed in neurons. Ace-x and ace-y genes are located in close proximity on chromosome II where they are separated by only a few hundred base pairs. The role of these two genes is still unknown.

cDNA sequence, gene structure, and cholinesterase-like domains of an esterase from Caenorhabditis elegans mapped to chromosome V.

The structure of an esterase gene from Caenorhabditis elegans has been determined by comparison of the sequences in genomic and cDNA clones. The gene was mapped close to the center of chromosome V (1.7 centimorgans to the left of dpy-11) and is therefore distinct from the gut esterase gene ges-1. It possessed 7 short introns. The 5' splice site of intron 3 presented the sequence GC instead of the usual GT that was found in the other six introns. The cDNA was trans-spliced with the short leader SL1. The open reading frame indicated that a protein of 557 aminoacids was encoded. The deduced aminoacid sequence did not present a signal peptide at the N-terminal but a potential N-myristoylation site (GXXXS) provided that the initiator methionine was removed. This protein should therefore remain intracellular. Comparison of this C. elegans sequence to other protein sequences in databases, as well as the analysis of the secondary structure in the protein showed that it belongs to the subgroup of esterases in the alpha/beta hydrolase fold family.

Engineering of immunogenic peptides by co-linear synthesis of determinants recognized by B and T cells.

The potential of synthetic peptides as vaccines is restricted by their frequent lack of immunogenicity. As with haptens, coupling to a carrier protein is usually required to provide T cell help to anti-peptide antibody-producing B cells. In spite of their short length, a few natural or synthetic peptides are immunogenic: they all include both a determinant recognized by B cells and a proven or putative determinant recognized by T cells. We speculated that it should be possible to induce immunogenicity in peptide haptens by the inclusion of a well characterized determinant recognized by T cells. We thus synthesized two peptides, corresponding to different regions of the major protein VP6 of bovine rotavirus, co-linearly linked to a peptide of influenza virus hemagglutinin which had been shown to induce T helper cells in BALB/c mice. Both peptides induced anti-rotavirus antibodies and were more immunogenic than the corresponding bovine serum albumin-conjugated peptides.

Enhancement of peptide immunogenicity by linear polymerization.

The effect of linear homopolymerization on the immunogenicity of synthetic peptides was studied using either haptenic peptides (representing amino acid sequences 103-115 and 133-147 of bovine rotavirus major protein) or immunogenic peptides TD-103-115 and TD-133-147 which were constructed by co-linear synthesis of the former peptides and an amino acid sequence representing a determinant recognized by T helper cells (TD). It was found that the two haptenic peptides were rendered immunogenic by linear homopolymerization. Moreover, homopolymerization also enhanced the immunogenicity of TD-103-115 but not that of TD-133-147. In the three cases where polymerization enhanced immunogenicity, a reinforced amphipathic pattern was predicted in the neighborhood of the junction of the monomers. The possibility that polymerization might have generated a new T cell determinant is discussed.

cDNA sequence, gene structure, and in vitro expression of ace-1, the gene encoding acetylcholinesterase of class A in the nematode Caenorhabditis elegans.

Three genes, ace-1, ace-2, and ace-3, encode three acetylcholinesterase classes (A, B, and C) in the nematode Caenorhabditis elegans. A fragment of genomic DNA was amplified by a polymerase chain reaction (PCR) using degenerate oligonucleotides based on sequences conserved in the cholinesterase family. This fragment mapped to chromosome X at a position that perfectly matched the location of ace-1 previously determined by genetic methods. Comparison of genomic and cDNA sequences showed that the open reading frame was interrupted by eight introns. The product of ace-1 (ACE-1, 620 amino acids) presented 42% identity with Torpedo and human acetylcholinesterases, 41% with human butyrylcholinesterase, and 35% with Drosophila acetylcholinesterase. The overall structure of cholinesterases was conserved in ACE-1 as indicated by the conserved sequence positions of Ser-216, His-468, and Glu-346 (S200, H440, E327 in Torpedo (AChE) as components of the catalytic triad, of the six cysteines which form three intrachain disulfide bonds, and of Trp-99(84), a critical side chain in the choline binding site. Spodoptera Sf9 cells were infected by a recombinant baculovirus containing ace-1 cDNA. The secreted enzyme was active and existed as hydrophilic 5 and 11.5 S molecular forms. It hydrolyzed both acetylthiocholine and butyrylthiocholine and was inhibited by acetylthiocholine above 10 mM.

Biochemical characterization of Drosophila melanogaster acetylcholinesterase expressed by recombinant baculoviruses.

Recombinant baculoviruses expressing full length and 3' truncated forms of c-DNA encoding the Drosophila melanogaster acetylcholinesterase (AChE) were constructed. Biochemical analyses showed that full length recombinant protein was enzymatically active and anchored to the cell membrane via a glycolipidic residue. DTT treatment dissociated the native form into monomers migrating as did the corresponding form of AChE extracted from drosophila heads. Finally, DFP labelling demonstrated that the specific proteolytic cleavage leading to the formation of 55 and 16 kDa subunits occurred in Sf9 cells. In contrast with the full-length enzyme, C-terminal-truncated forms were highly secreted, confirming the prominent role of the C-terminal hydrophobic peptide for the addition of the glycolipidic residue. Accumulation of inactive precursor was observed when recombinant proteins were overproduced using an improved baculovirus, suggesting a saturation of insect cell machineries.