A cytoplasmic dynein heavy chain in sea urchin embryos.

By making the hypothesis that the pattern of conserved sequence residues in the vicinity of the hydrolytic ATP-binding site of dynein would resemble that in myosins from a broad variety of sources, we designed degenerate oligonucleotide primers capable of amplifying this region of multiple dynein isoforms from sea urchin embryo poly(A)+ RNA. Quantification of the expression of two of these dynein isoforms has shown that the level of mRNA encoding for the beta-heavy chain, like that of tubulin, increases 2-3-fold after deciliation of the embryos, whereas the expression of the second dynein isoform, like that of actin, is essentially unaffected. This second isoform is believed to be the cytoplasmic dynein of sea urchin embryos.     

Identification of dynein heavy chain genes expressed in human and mouse testis: chromosomal localization of an axonemal dynein gene

Dynein heavy chains are involved in microtubule-dependent transport processes. While cytoplasmic dyneins are involved in chromosome or vesicle movement, axonemal dyneins are essential for motility of cilia and flagella. Here we report the isolation of dynein heavy chain (DHC)-like sequences in man and mouse. Using polymerase chain reaction and reverse-transcribed human and mouse testis RNA cDNA fragments encoding the conserved ATP binding region of dynein heavy chains were amplified. We identified 11 different mouse and eight human dynein-like sequences in testis which show high similarity to known dyneins of different species such as rat, sea urchin or green algae. Sequence similarities suggest that two of the mouse clones and one human clone encode putative cytoplasmic dynein heavy chains, whereas the other sequences show higher similarity to axonemal dyneins. Two of nine axonemal dynein isoforms identified in the mouse testis are more closely related to known outer arm dyneins, while seven clones seem to belong to the inner arm dynein group. Of the isolated human isoforms three clones were classified as outer arm and four clones as inner arm dynein heavy chains. Each of the DHC cDNAs corresponds to an individual gene as determined by Southern blot experiments. The alignment of the deduced protein sequences between human (HDHC) and mouse (MDHC) dynein fragments reveals higher similarity between single human and mouse sequences than between two sequences of the same species. Human and mouse cDNA fragments were used to isolate genomic clones. Two of these clones, gHDHC7 and gMDHC7, are homologous genes encoding axonemal inner arm dyneins. While the human clone is assigned to 3p21, the mouse gene maps to chromosome 14.     

Cloning of dynein intermediate chain cDNA of the newt Cynops pyrrhogaster.

To isolate genes whose expression is up-regulated after initiation of meiosis, we employed an mRNA differential display method using RNA extracted from newt testis fragments in the spermatogonial and spermatocyte stages. We report here isolation of a spermatocyte stage-specific cDNA clone encoding a newt homologue of dynein intermediate chain (IC). The newt dynein IC cDNA was found to encode a polypeptide consisting of 694 amino acid residues with 66.8% and 45.8% amino acid sequence similarity to sea urchin dynein IC3 and Chlamydomonas IC69, respectively. The predicted protein contains five WD repeats and a novel repeated motif in the C-terminal region. Northern blot analysis revealed that newt dynein IC mRNA was expressed in the spermatocyte and round spermatid stages, suggesting that dynein IC plays a role in formation of flagella as well as in meiotic events.     

Brain-specific expression of MAP2 detected using a cloned cDNA probe

We describe the isolation of a set of overlapping cDNAs encoding mouse microtubule associated protein 2 (MAP2), using an anti-MAP antiserum to screen a mouse brain cDNA expression library cloned in bacteriophage lambda gt11. The authenticity of these clones was established by the following criteria: (a) three non-identical clones each expressing a MAP2 immunoreactive fusion protein were independently isolated from the expression library; each of these clones cross-hybridized at the nucleic acid level; (b) anti-MAP antiserum was affinity purified using nitrocellulose-bound fusion protein; these antibodies detected only MAP2 in an immunoblot experiment of whole brain microtubule protein; (c) a series of cDNA "walking" experiments was done so as to obtain a non-overlapping cloned fragment corresponding to a different part of the same mRNA molecule. Upon subcloning this non-overlapping fragment into plasmid expression vectors, a fusion protein was synthesized that was immunoreactive with an anti-MAP2 specific antiserum. Thus, a single contiguous cloned mRNA molecule encodes at least two MAP2-specific epitopes; (d) the cloned cDNA probes detect an mRNA species in mouse brain that is of a size (approximately 9 kb) consistent with the coding capacity required by a 250,000-D protein. The MAP2-specific cloned cDNA probes were used in RNA blot transfer experiments to assay for the presence of MAP2 mRNA in a variety of mouse tissues. Though brain contained abundant quantities of MAP2 mRNA, no corresponding sequences were detectable in RNA prepared from liver, kidney, spleen, stomach, or thymus. We conclude that the expression of MAP2 is brain-specific. Use of the MAP2 specific cDNA probes in genomic Southern blot transfer experiments showed the presence of a single gene encoding MAP2 in mouse. The microheterogeneity of MAP2 is therefore ascribable either to alternative splicing within a single gene, or to posttranslational modification(s), or both. Under conditions of low stringency, the mouse MAP2 cDNA probe cross-hybridizes with genomic sequences from rat, human, and (weakly) chicken, but not with sequences in frog, Drosophila, or sea urchin DNA. Thus, there is significant interspecies divergence of MAP2 sequences. The implications of the above observations are discussed in relationship to the potential biological function of MAP2.     

A cloned cDNA encoding MAP1 detects a single copy gene in mouse and a brain-abundant RNA whose level decreases during development

Screening of a bacteriophage lambda gt11 cDNA expression library with a polyclonal anti-microtubule associated protein (MAP) antiserum resulted in the isolation of two non-cross-hybridizing sets of cDNA clones. One set was shown to encode MAP2 (Lewis, S. A., A. Villasante, P. Sherline, and N. J. Cowan, 1986, J. Cell Biol., 102:2098-2105). To determine the specificity of the second set, three non-overlapping fragments cloned from the same mRNA molecule via a series of "walking" experiments were separately subcloned into inducible plasmid expression vectors in the appropriate orientation and reading frame. Upon induction and analysis by immunoblotting, two of the fusion proteins synthesized were shown to be immunoreactive with an anti-MAP1-specific antibody, but not with an anti-MAP2-specific antibody. Since these MAP1-specific epitopes are encoded in non-overlapping cDNAs cloned from a single contiguous mRNA, these clones cannot encode polypeptides that contain adventitiously cross-reactive epitopes. Furthermore, these cDNA clones detected an abundant mRNA species of greater than 10 kb in mouse brain, consistent with the coding requirement of a 350,000-D polypeptide and the known abundance of MAP1 in that tissue. The MAP1-specific cDNA probes were used in blot transfer experiments with RNA prepared from brain, liver, kidney, stomach, spleen, and thymus. While detectable quantities of MAP1-specific mRNA were observed in these tissues, the level of MAP1 expression was approximately 500-fold lower than in brain. The levels of both MAP1-specific and MAP2-specific mRNAs decline in the postnatal developing brain; the level of MAP1-specific mRNA also increases slightly in rat PC12 cells upon exposure to nerve growth factor. These surprising results contrast sharply with reported dramatic developmental increases in the amount of MAP1 in brain and in nerve growth factor-induced PC12 cells. The cDNA clones encoding MAP1 detect a single copy sequence in mouse DNA, even under conditions of low stringency that would allow the detection of related but mismatched sequences. The cDNAs cross-hybridize with genomic sequences in rat, human, and chicken DNA, but not with DNA from frog, Drosophila, or sea urchin. These data are discussed in terms of the evolution and possible biological role of MAP1.     

Evidence suggesting the presence of common antigenic determinant between dynein and tubulin.

The present experiments showed that the guinea pig antiserum prepared against the main polypeptides of 14 S dynein from Tetrahymena cilia reacted with sea urchin sperm flagellar dynein and with bovine brain high molecular weight protein to give rise to a precipitin line confluent with that formed between the antiserum and Tetrahymena dynein. Furthermore, it was found that this antiserum also reacted with tubulins from Tetrahymena cilia, sea urchin sperm flagella and bovine brain to give rise to the confluent precipitin line. Among muscle proteins, only actin preparation from rabbit skeletal muscle reacted with the anti-Tetrahymena dynein serum, whereas neither rabbit skeletal muscle myosin, chicken skeletal muscle tropomyosin nor chicken skeletal muscle troponin reacted with the antiserum. These results suggest that dynein and tubulin and probably actin share an antigenic determinant regardless of different protein species and of different animal species. The common antigenic determinant was detected only when the proteins denatured with urea/sodium dodecyl sulfate/beta-mercaptoethanol/N-ethylmaleimide were used, but it was not detected at all when the native proteins were used. This implies that a certain common antigenic determinant which is involved in the precipitin line formation exists in the primary structures of dyneins and tubulins and probably actin, and is hidden inside the tertiary structures of the native protein molecules.     

Molecular cloning and temporal expression during pregnancy of the messenger ribonucleic acid encoding uteroferrin, a progesterone-induced uterine secretory protein

A lambda gt11 expression library containing cDNA inserts prepared from porcine endometrial mRNA was immunologically screened by using an antiserum developed against porcine uteroferrin (Uf), a glycoprotein that has been strongly implicated in transplacental iron transport in the pregnant pig. Antibody reactive clones (lambda 4a3, 13.1, and 2.2) were isolated after screening 1.5 x 10(5) recombinant phages. Clones 4a3 and 13.1 expressed Uf antigenic determinants in beta-galactosidase fusion proteins and specifically selected antibody which reacted with Uf in immunoblots prepared from uterine cytosolic extracts. In addition, all three cDNA clones collectively contained DNA sequences that encoded an 85-amino acid peptide which corresponded to a region within the carboxyterminal portion of the Uf protein. Northern blot hybridization of these cDNAs to RNAs extracted from whole uterine tissue of pregnant pigs revealed a single uterine poly(A)+ RNA of approximately 1.7 kilobases in length, which was not found in liver and mammary tissue RNAs. The concentration of the Uf mRNA changed in a temporal fashion during pregnancy in a manner that was distinct from that of the progesterone receptor mRNAs. Highest levels of Uf mRNA were found at mid and late pregnancy (days 45-110) and were about 50-fold greater than at day 30 of pregnancy. By contrast, RIA analysis of the uterine tissue extracts showed that maximum amounts of Uf were present at day 60 and then declined sharply. Thus the pattern of Uf mRNA present in the uterus did not parallel the amount of Uf polypeptide that could be recovered from the tissue. The tissue specific and temporal regulation of Uf gene expression emphasizes that the protein plays an important role in uterine activity and/or fetal development.     

Molecular cloning of the carboxy terminus of a canine tracheobronchial mucin.

A cDNA library constructed from canine tracheal mRNA was screened with polyclonal antiserum specific to canine tracheal apomucin (CTM-A). Eight antibody reactive clones were isolated and purified to clonality. One of the clones, designated pCTM-A, had a 1.7 kb insert and included a single open reading frame with a poly (A)+ tail. The amino acid composition of the encoded protein was consistent with that expected for CTM-A. The fusion protein produced by cloning the 1.7 kb insert in the pMALc expression vector reacted with the purified anti-apomucin CTM-A antibody. Also, polyclonal antibodies raised to the purified protein product encoded by pCTM-A reacted with deglycosylated CTM-A confirming that this clone does indeed code for apomucin CTM-A. This is the first report of a cDNA encoding the C-terminus of a canine tracheal mucin.     

Identification of a putative isoform of the Na,K-ATPase beta subunit. Primary structure and tissue-specific expression

We have isolated cDNA clones from rat brain and human liver encoding a putative isoform of the Na,K-ATPase beta subunit. The rat brain cDNA contains an open reading frame of 870 nucleotides coding for a protein of 290 amino acids with a calculated molecular weight of 33,412. The corresponding amino acid sequence shows 98% identity with its human liver counterpart. The proteins encoded by the rat and human cDNAs exhibit a high degree of primary sequence and secondary structure similarity with the rat Na,K-ATPase beta subunit. We have therefore termed the polypeptides these cDNAs encode a beta 2 subunit with the previously characterized rat cDNA encoding a beta 1 subunit. Analysis of rat tissue RNA reveals that the beta 2 subunit gene encodes a 3.4-kilobase mRNA which is expressed in a tissue specific fashion distinct from that of rat beta 1 subunit mRNA. Cell lines derived from the rat central nervous system shown to lack beta 1 subunit mRNA sequences were found to express beta 2 subunit mRNA. These results suggest that different members of the Na,K-ATPase beta subunit family may have specialized functions.     

Molecular cloning and nucleotide sequence of cDNA encoding hydroxyindole O-methyltransferase of bovine pineal glands

Messenger RNA for hydroxyindole O-methyltransferase (EC 2.1.1.4) was partially purified from poly(A)+ RNA isolated from bovine pineal glands by sucrose density gradient centrifugation. The enriched mRNA was used to prepare a cDNA library by use of expression vector lambda gt11. The library was screened with monoclonal antibodies to the enzyme, and three cDNA clones were isolated. These cloned cDNAs cross-hybridized with one another, and their fusion proteins reacted to the monoclonal antibodies with different binding properties. Hydroxyindole O-methyltransferase enzymatic activity was demonstrated in the bacteria lysate infected with lambda HIOMT-A16, the clone that contained the longest insert. An almost full-length cDNA clone was isolated from lambda gt10 cDNA library by use of the lambda HIOMT-A16 cDNA as a probe. The primary structure of hydroxyindole O-methyltransferase was determined by analyzing the nucleotide sequence of the cDNAs. It consisted of 1939 nucleotides including a 1050-nucleotide region coding for 350 amino acids. RNA transfer blot analysis indicated that mRNA encoding hydroxyindole O-methyltransferase was present only in the pineal gland and not in the brain, retina, and liver of cow.     

Antibodies to cytoplasmic dynein heavy chain map the surface and inhibit motility

Polyclonal antibodies have been raised against four 16 residue peptides with sequences taken from the C-terminal quarter of the human cytoplasmic dynein heavy chain. The sites are downstream from a known microtubule-binding domain associated with the "stalk" that protrudes from the motor domain. The antisera were assayed using bacterially expressed proteins with amino acid sequences taken from the human cytoplasmic dynein heavy chain. Every antiserum reacted specifically with the appropriate expressed protein and with pig brain cytoplasmic dynein, whether the protein molecules were denatured on Western blots or were in a folded state. But, whereas three of the four antisera recognized freshly purified cytoplasmic dynein, the fourth reacted only with dynein that had been allowed to denature a little. After affinity purification against the expressed domains, whole IgG molecules and Fab fragments were assayed for their effect on dynein activity in in vitro microtubule-sliding assays. Of the three anti-peptides that reacted with fresh dynein, one inhibited motility but the others did not. The way these peptides are exposed on the surface is compatible with a model whereby the dynein motor domain is constructed from a ring of AAA protein modules, with the C-terminal module positioned on the surface that interacts with microtubules. We have tentatively identified an additional AAA module in the dynein heavy chain sequence, which would be consistent with a heptameric ring.     

Isolation and characterization of a cDNA coding for human myeloperoxidase

A cDNA encoding the carboxyl-terminal fragment of the human myeloperoxidase heavy chain was isolated and characterized. It was then used to determine the locations of the myeloperoxidase light and heavy chains in the polypeptide precursor. A cDNA library from poly(A)+ RNA from human leukemia HL-60 cells was constructed in pBR322 and screened by differential hybridization with enriched and depleted cDNA probes and then by hybridization with an oligonucleotide probe. A cDNA clone containing 1278 bp with an open reading frame of 474 bp and a 3' noncoding region of 804 bp was isolated. The amino acid sequence deduced from the nucleotide sequence consisted of 158 residues including a sequence of 14 amino acids known to be present in the heavy chain of the molecule. The cDNA also included a stop codon of TAG followed by a noncoding sequence that included a potential recognition site for polyadenylylation and a poly(A) tail. RNA transfer blot analysis with the cDNA probe indicated that myeloperoxidase mRNA was approximately 3.3 kb in length. In vitro translation of the mRNA selected by cDNA hybridization revealed preferential synthesis of a 74,000-Da polypeptide precursor that could be precipitated with anti-myeloperoxidase IgG. Antibodies specific for the heavy and light chains of myeloperoxidase were isolated from antiserum by affinity chromatography employing Sepharose columns covalently bound to the heavy or light chains. Antibodies specific for the light chain or the heavy chain readily precipitated the 74,000-Da precursor polypeptide. These results indicated that myeloperoxidase is synthesized as a single chain which undergoes processing into a light and heavy chain. Furthermore, the heavy chain of myeloperoxidase originates from the carboxyl terminus of the precursor polypeptide.     

Identification of functional murine adenosine deaminase cDNA clones by complementation in Escherichia coli

Total poly(A+) RNA derived from a mouse cell line with amplified adenosine deaminase genes was used as template to synthesize double-stranded cDNA. The cDNAs were inserted into the PstI site of the beta-lactamase gene in plasmid pBR322 following G-C tailing. After transformation into adenosine deaminase-deficient Escherichia coli hosts, recombinant plasmids containing functional murine adenosine deaminase cDNAs were identified by selecting for functional complementation. Analysis of plasmids containing functional adenosine deaminase cDNA sequences strongly suggested that adenosine deaminase expression resulted mainly from beta-lactamase/adenosine deaminase fusion proteins even when the adenosine deaminase codons were out-of-frame with respect to the beta-lactamase gene codons upstream. The nucleotide sequence of a 1.65-kilobase pair cDNA insert in one of the functional recombinant clones was determined and found to contain a 1056-nucleotide open reading frame. When this 1056-nucleotide open reading frame was inserted into a mammalian expression vector and introduced into monkey kidney cells, a high level of authentic mouse adenosine deaminase was produced. Nucleic acid blot analysis using a full-length adenosine deaminase cDNA clone as probe revealed that the mouse adenosine deaminase structural gene was at least 21 kilobase pairs in size and encoded three polyadenylated mRNAs. Analysis of the cDNA library from which the functional clones were isolated suggested that this approach of cloning functional mammalian adenosine deaminase cDNA clones by genetic complementation of enzyme-deficient bacteria could be accomplished even if the abundance of the adenosine deaminase mRNA sequences were as low as approximately 0.001%.     

The cDNA of the two isoforms of bovine cGMP-dependent protein kinase

cDNAs encoding the isoform I alpha of the cGMP-dependent protein kinase were isolated from a bovine trachea smooth muscle cDNA library constructed in lambda gt10. The deduced protein sequence is identical with the protein sequence obtained by Edman degradation of the bovine lung enzyme [(1984) Biochemistry 23, 4207-4218]. Alternate cDNA clones were isolated which code for a protein slightly different within the aminoterminal part from the known amino acid sequence. These alternate cDNAs contain the sequence of a peptide identified in the isoform I beta of cGMP-dependent protein kinase. Northern blot analysis of poly(A)+ RNA from bovine trachea smooth muscle indicated the presence of two different mRNA species of about 6.2 kb.