Isolation of a cDNA clone for a catalytic subunit of Torpedo marmorata acetylcholinesterase

We have constructed a cDNA library from Torpedo marmorata electric organ poly(A+) RNA in the lambda phage expression vector lambda gt11. This library has been screened with polyclonal anti-acetylcholinesterase antibodies. One clone, lambda AChE1, produced a fusion protein which was recognized by the antibodies and which prevented the binding of native acetylcholinesterase in an enzymatic immune assay. These results indicate that lambda AChE1 contains a cDNA insert coding for a part of a catalytic subunit of Torpedo acetylcholinesterase. The 200-base-pair cDNA insert hybridized to three mRNAs (14.5, 10.5 and 5.5 kb) from Torpedo electric organs. These mRNAs were also detected in Torpedo electric lobes.     

Molecular cloning and expression of a full-length cDNA encoding acetylcholinesterase in optic lobes of the squid Loligo opalescens: a new member of the cholinesterase family resistant to diisopropyl fluorophosphate

Acetylcholinesterase cDNA was cloned by screening a library from Loligo opalescens optic lobes; cDNA sequence analysis revealed an open reading frame coding for a protein of 610 amino acids that showed 20-41% amino acid identity with the acetylcholinesterases studied so far. The characteristic structure of cholinesterase (the choline binding site, the catalytic triad, and six cysteines that form three intrachain disulfide bonds) was conserved in the protein. The heterologous expression of acetylcholinesterase in COS cells gave a recovery of acetylcholinesterase activity 20-fold higher than in controls. The enzyme, partially purified by affinity chromatography, showed molecular and kinetic features indistinguishable from those of acetylcholinesterase expressed in vivo, which displays a high catalytic efficiency. Both enzymes are true acetylcholinesterase corresponding to phosphatidylinositol-anchored G2a dimers of class I, with a marked substrate specificity for acetylthiocholine. The deduced amino acid sequence may explain some particular kinetic characteristics of Loligo acetylcholinesterase, because the presence of a polar amino acid residue (S313) instead of a nonpolar one [F(288) in Torpedo] in the acyl pocket of the active site could justify the high substrate specificity of the enzyme, the absence of hydrolysis with butyrylthiocholine, and the poor inhibition by the organophosphate diisopropyl fluorophosphate.     

Synthesis in vitro of precursors of the catalytic subunits of acetylcholinesterase from Torpedo marmorata and Electrophorus electricus

We translated poly(A-rich messenger RNA prepared from the electric organs of Electrophorus electricus and Torpedo marmorata in a reticulocyte lysate system. In the case of Electrophorus, which appears to contain only one type of acetylcholinesterase catalytic subunit, an anti-(Electrophorus acetylcholinesterase) antiserum precipitated a single 65-kDa polypeptide from the products translation obtained in vitro. In the case of Torpedo, where a number of distinct catalytic subunits corresponding to different fractions of the enzyme have been described, an anti-(Torpedo acetylcholinesterase) antiserum precipitated two main polypeptides, 61 kDa and 65 kDa, both of which could be displaced by unlabelled purified Torpedo acetylcholinesterase. Synthesis in vitro thus appears to produce a single type of precursor of the acetylcholinesterase catalytic subunit for Electrophorus, and at least two distinct precursors for Torpedo, suggesting that several mRNAs code for the catalytic subunits in the latter species.     

Primary structure of acetylcholinesterase: implications for regulation and function

A cDNA encoding acetylcholinesterase (AChE) (EC 3.1.1.7) from Torpedo californica was isolated and from its nucleotide sequence the entire amino acid sequence of the processed protein and a portion of the leader peptide has been deduced. Approximately 70% of the tryptic peptides from the catalytic subunit of the 11 S form have been sequenced, and a comparison of the peptide sequences with the sequence inferred from the cDNA suggests that the cDNA sequence derives from mRNA for the 11 S form of the enzyme. The amino acid sequence is preceded by a hydrophobic leader peptide and contains an open reading frame encoding for 575 amino acids characteristic of a secreted globular protein. Eight cysteines, most of which are disulfide linked, are found along with four potential sites of N-linked glycosylation. The active-site serine is located at residue 200. Local homology is found with other serine hydrolases in the vicinity of the active site, but the enzyme shows striking global homology with the COOH-terminal portion of thyroglobulin. Further comparison of the amino acid sequences of the individual enzyme forms with other cDNA clones that have been isolated should resolve the molecular basis for polymorphism of the AChE species.     

Multiple messenger RNA species give rise to the structural diversity in acetylcholinesterase

Acetylcholinesterase exists predominantly as a secreted enzyme which remains cell-associated at specific extracellular locations. Its extensive structural diversity appears responsible for the unique cellular disposition of the enzyme. To examine the molecular basis of the structural divergence of acetylcholinesterase species, we hybridized total RNA from Torpedo californica electric organ with restriction fragments from a cDNA encoding the catalytic subunits of asymmetric species of acetylcholinesterase. Multiple RNA species up to 14 kilobases in length can be detected on Northern blots using a full-length cDNA for hybridization. Each of these RNA species also hybridizes with smaller restriction fragments within the open reading frame and 3'-untranslated region of the cDNA. This indicates that the entire open reading frame plus the 3'-untranslated region is contained in the large RNA species. RNase protection experiments revealed at least three points of divergence for the message species. One occurs within the COOH-terminal portion of the open reading frame at a position just 5' to the TGA stop codon. This divergence accounts for the two classes of acetylcholinesterase found in abundance in Torpedo. The site of splicing has been further defined by isolating a genomic clone containing the exon serving as the potential splice donor. We find a divergence between the cDNA and genomic DNA at the position estimated by the protection experiments. A less abundant divergence in mRNA can also be detected in the 3'-untranslated region. Another divergence occurs as a deleted sequence within the 5'-noncoding region and may be important for controlling translation efficiency. Since it is hypothesized that a single gene encodes acetylcholinesterase, the divergences in the very 3' region of the open reading frame and the 5'-noncoding region correspond to presumed splice junction boundaries where alternative RNA splicing occurs.     

Torpedo marmorata acetylcholinesterase; a comparison with the Electrophorus electricus enzyme. Molecular forms, subunits, electron microscopy, immunological relationship.

Electron microscopy, sequential degradation by hydrolytic enzymes and the physical-chemical properties of the molecular forms of Torpedo acetylcholinesterase indicate that these molecules are structurally related to each other in the same way as the molecular forms of Electrophorus acetylcholinesterase: all are derived from a complex structure in which three tetrameric groups of subunits are associated with a rod-like 'tail'. In aged preparations the catalytic subunits are split into fragments in a manner similar to those of Electrophorus acetylcholinesterase. Immunological cross-reaction between both enzymes demonstrates the occurrence of common antigenic sites. The enzymes from the two sources, however, are different in their molecular weights and susceptibility to hydrolytic enzymes. Also, Torpedo acetylcholinesterase does not precipitate with either isologous or heterologous antibodies.     

The Ace locus of Drosophila melanogaster: structural gene for acetylcholinesterase with an unusual 5'' leader.

The Ace locus of Drosophila melanogaster has been mapped at the molecular level. cDNA clones from the locus have been isolated and their sequence determined, confirming that Ace forms the structural gene for acetylcholinesterase (AChE). The cDNAs have a 1950 nucleotide open reading frame from which the complete amino acid sequence of AChE has been deduced. The Drosophila enzyme is found to have extensive homology to the known sequence of Torpedo AChE. Ace cDNAs have an unusual structure with a long 5' leader and several short upstream open reading frames.     

Primary structures of two types of alpha-subunit of rat brain Na+,K+,-ATPase deduced from cDNA sequences

A rat brain cDNA library was screened by using as a probe a fragment of cDNA encoding the alpha-subunit of human Na+,K+-ATPase. Two different cDNA clones were obtained and analyzed. One of them was concluded to be a cDNA encoding the alpha-subunit of the weakly ouabain-sensitive rat kidney-type Na+,K+-ATPase. The deduced amino acid sequence consists of 1,018 amino acids. The alpha-subunit of the rat kidney-type Na+,K+-ATPase shows 97% homology in amino acid sequence with the alpha-subunit of human, sheep, or pig enzyme and 87% with that of Torpedo. Based on a comparison of the amino acid sequence at the extracellular domain of the alpha-subunit between weakly ouabain-sensitive rat kidney-type enzyme and the ouabain-sensitive human, sheep, pig, or Torpedo enzyme, it was proposed that only two significant amino acid replacements are unique to the rat kidney-type alpha-subunit. Another cDNA clone obtained showed 72% homology in nucleotide sequence with the former cDNA coding the alpha-subunit of the rat kidney-type Na+,K+-ATPase and the deduced amino acid sequence exhibited 85% homology with that of the alpha-subunit of rat kidney-type Na+,K+-ATPase.     

Molecular cloning and nucleotide sequence of cDNAs encoding the precursors of rat long chain acyl-coenzyme A, short chain acyl-coenzyme A, and isovaleryl-coenzyme A dehydrogenases. Sequence homology of four enzymes of the acyl-CoA dehydrogenase family

cDNAs encoding the entire coding regions of the precursors (p) of rat long chain acyl-CoA (LCAD), short chain acyl-CoA (SCAD) and isovaleryl-CoA dehydrogenase (IVD) have been cloned and sequenced. Three cDNAs for rat liver LCAD together cover a 1440-base pair region. These cDNAs encode the entire 430-amino acid sequence of pLCAD, including the 30-amino acid leader peptide and the 400-amino acid mature LCAD. A single 1773 base pair cDNA for rat SCAD covers the entire coding region (414 amino acids), including the 26-amino acid leader peptide and the 388-amino acid mature peptide. Four identified IVD cDNAs, when combined, encompass a 2104 base region, and encode 424 amino acids including a 30-amino acid leader peptide and the 394-amino acid mature peptide. The identities of all cDNA clones have been confirmed by matching the amino acid sequences predicted from the respective cDNAs to the amino-terminal and tryptic peptide sequences derived from the corresponding purified rat enzyme. Comparison of the sequences of four rat acyl-CoA dehydrogenases, including LCAD, MCAD, SCAD, and IVD, and two of their human counterparts (MCAD and SCAD) reveals a high degree of homology (57 invariant and 92 near invariant residues: 30.6-35.4% of identical residues in pairwise comparisons), suggesting that these enzymes belong to a gene family and have evolved from a common ancestral gene.     

Molecular cloning and sequence analysis of cDNA coding for canine gastrin

We have isolated and sequenced cDNA clones encoding for preprogastrin from a canine antral cDNA library. Comparison of this sequence with those of porcine, human, and rat gastrin reveals extensive (83%) homology in the gastrin coding region as well as short regions of conserved nucleotides in the noncoding regions. The canine sequence encodes a preprogastrin of 104 amino acids which consists of a signal peptide, a 37-amino acid prosegment, and a 34-amino acid gastrin sequence, followed by a glycine (the amide donor), and flanked by pairs of arginine residues.     

Inactive Monomeric Acetyleholinesterase in the Low-Salt-Soluble Extract of the Electric Organ from Torpedo marmorata

Proteolytic fragmentation of [3H]diisopropylfluorophosphate-labelled catalytic subunits of different molecular forms of acetylcholinesterase demonstrates that all forms extracted from the electric organ from Torpedo marmorata are true acetylcholinesterases. This is supported by immunochemical results showing that the radiolabelled polypeptides are readily recognized by specific anti-acetylcholinesterase antibodies. Although distinct structural differences exist, all forms contain a similar peptide carrying the serine hydroxyl of the esteratic subsite. Dimeric, detergent-soluble acetylcholinesterase is present in the low-salt-soluble extract (Mr of the catalytic subunit 66,000) together with a monomeric form (apparent Mr 76,000). This monomeric polypeptide is hydrophilic, enzymatically inactive, and might represent a precursor of the asymmetric forms of acetylcholinesterase.     

Wound-induced proteinase inhibitors from tomato leaves. I. The cDNA-deduced primary structure of pre-inhibitor I and its post-translational processing

A cDNA containing the coding region for the complete amino acid sequence of wound-induced proteinase Inhibitor I from tomato leaves was constructed in the plasmid pUC9 and characterized. The open reading frame codes for a protein of 111 amino acids. This deduced amino acid sequence revealed the presence of a 42-amino acid N-terminal sequence that is not found in the native protein. This sequence appears to contain a 23-amino acid segment typical of a signal sequence followed by a 19-amino acid sequence containing 9 charged amino acids. The 42-amino acid sequence is apparently lost during maturation to the native Inhibitor I and represents 38% of the translated protein. The Inhibitor I amino acid sequence contains 71% identity with potato tuber Inhibitor I sequence and 35% identity with an inhibitor from the leech.     

A single WAP domain-containing protein from Litopenaeus vannamei hemocytes

A cDNA clone coding for a single WAP domain (SWD) protein was isolated from a hemocyte cDNA library of Litopenaeus vannamei. The full-length cDNA sequence is 0.4kb long and encodes a 93-amino acid protein. Using this sequence as a probe a similar clone coding for a 92-amino acids protein was found in a cDNA library from Penaeus monodon hemocytes. The mRNA size was confirmed by Northern blot as well as that gene is expressed in hemocytes, but not in hepatopancreas. mRNA levels of the shrimp SWD protein were modified after injection of Vibrio alginolyticus, indicating the probable role of this protein in the immune response. Although amino acid sequence seems to be similar to those of other WAP domain-containing proteins, shrimp SWD protein does not have any other functional domain, similar to a mouse single WAP motif (SWAM) protein reported in mouse; however, the phylogenetic analysis shows that shrimp SWD is more related to other WAP proteins than to mouse SWAM.     

Kinetic and structural studies on the interaction of cholinesterases with the anti-Alzheimer drug rivastigmine

Rivastigmine, a carbamate inhibitor of acetylcholinesterase, is already in use for treatment of Alzheimer's disease under the trade name of Exelon. Rivastigmine carbamylates Torpedo californica acetylcholinesterase very slowly (k(i) = 2.0 M(-1) min(-1)), whereas the bimolecular rate constant for inhibition of human acetylcholinesterase is >1600-fold higher (k(i) = 3300 M(-1) min(-1)). For human butyrylcholinesterase and for Drosophila melanogaster acetylcholinesterase, carbamylation is even more rapid (k(i) = 9 x 10(4) and 5 x 10(5) M(-1) min(-1), respectively). Spontaneous reactivation of all four conjugates is very slow, with <10% reactivation being observed for the Torpedo enzyme after 48 h. The crystal structure of the conjugate of rivastigmine with Torpedo acetylcholinesterase was determined to 2.2 A resolution. It revealed that the carbamyl moiety is covalently linked to the active-site serine, with the leaving group, (-)-S-3-[1-(dimethylamino)ethyl]phenol, being retained in the "anionic" site. A significant movement of the active-site histidine (H440) away from its normal hydrogen-bonded partner, E327, was observed, resulting in disruption of the catalytic triad. This movement may provide an explanation for the unusually slow kinetics of reactivation.     

Site-directed mutagenesis of active-site-related residues in Torpedo acetylcholinesterase. Presence of a glutamic acid in the catalytic triad.

Site-directed mutagenesis was used to investigate the role of acidic amino acid residues close to the active site of Torpedo acetylcholinesterase. The recently determined atomic structure of this enzyme shows the conserved Glu-327, together with His-440 and Ser-200 as forming a catalytic triad, while the adjacent conserved Asp-326 points away from the active site. Transfection of appropriately mutated DNA into COS cells showed that the mutation of Asp-326----Asn had little effect on catalytic activity or the molecular forms expressed, suggesting no crucial structural or functional role for this residue. Mutation of Glu-327 to Gln or to Asp led to an inactive product. These results support the conclusions of the structural analysis for the two acidic residues.     

Molecular cloning and sequence analysis of human Na,K-ATPase beta-subunit.

We have isolated a cDNA clone for the beta-subunit of HeLa cell Na,K-ATPase, containing a 2208-base-pair cDNA insert covering the whole coding region of the beta-subunit. Nucleotide sequence analysis revealed that the amino acid sequence of human Na,K-ATPase exhibited 61% homology with that of Torpedo counterpart (Noguchi et al. (1986) FEBS Lett. in press). A remarkable conservation in the nucleotide sequence of the 3' non-coding region was detected between the human and Torpedo cDNAs. RNA blot hybridization analysis revealed the presence of two mRNA species in HeLa cells. S1 nuclease mapping indicated that they were derived from utilization of two distinct polyadenylation signals in vivo. Total genomic Southern hybridization indicated the existence of only a few, possibly one set of gene encoding the Na,K-ATPase beta-subunit in the human genome.