The genes coding for the cytoskeletal proteins actin and vimentin in warm-blooded vertebrates

Recombinant plasmids were made containing cDNAs synthesized on hamster mRNAs coding for cytoskeletal (beta- or gamma-) actins and for vimentin. Hybridization of the actin probe on restriction digests of one avian and five mammalian DNAs yielded multiple bands; the vimentin probe revealed only one band (accompanied by 2-3 faint bands in some DNAs). The results obtained with the vimentin probe indicate that the corresponding coding sequences: (a) are highly conserved in warm-blooded vertebrates like the actin sequences; (b) have strongly diverged from those coding for other intermediate filament proteins, since hybridization of the vimentin probe does not lead to a diagnostic multiband pattern; and (c) most likely contribute to single gene, in contrast to the sequences coding for other cytoskeletal proteins. Hybridization of the probes on mRNAs from the different sources used showed that the non-coding sequences of both vimentin and actin genes are conserved in length.     

High-level expression of RNAs and proteins: the use of oligonucleotides for the precise fusion of coding-to-regulatory sequences

We show that the fusion between regulatory sequences present on expression vectors and coding sequences can be efficiently achieved by oligonucleotide-directed mutagenesis. We have constructed single-stranded (ss) expression vectors that facilitate this process. These plasmids derive from vectors that have been used for the synthesis of quantities of proteins in Escherichia coli or RNAs in vitro. By inserting the origin of replication of the ss phage f1 into these plasmids it became possible to package their ss DNA into phage rods. Deletion of unwanted sequences or simple base changes can then be obtained by oligonucleotide-directed mutagenesis using the vector ss DNA as a template. We discuss the results of several experiments where this technique was applied to our expression vectors and we demonstrate the construction of a plasmid which efficiently synthesizes in vitro a regulatory RNA molecule that is involved in the control of plasmid copy number.     

Construction of bacterial plasmids containing sequences complementary to chicken alpha-tropomyosin mRNA.

Recombinant plasmids have been constructed with contain sequences complementary to the mRNA coding for skeletal muscle alpha-tropomyosin. These recombinants were detected initially using a selective cDNA probe and subsequently using a messenger RNA selection assay. alpha-TM plasmids hybridize to a singly mRNA species smaller than 18S ribosomal RNA and found only in skeletal muscle. Cross-hybridization with mRNA's coding for other tropomyosins could not be detected under normal conditions. However, under conditions of reduced stringency alpha- TM plasmids cross-hydridize with an RNA species in heart muscle which may code for cardiac tropomyosin.     

Genetic relationships among 527 Gram-negative bacterial plasmids

Plasmids are mosaic in composition with a maintenance "backbone" as well as "accessory" genes obtained via horizontal gene transfer. This horizontal gene transfer complicates the study of their genetic relationships. We describe a method for relating a large number of Gram-negative (GN) bacterial plasmids based on their genetic sequences. Complete coding gene sequences of 527 GN bacterial plasmids were obtained from NCBI. Initial classification of their genetic relationships was accomplished using a computational approach analogous to hybridization of "mixed-genome microarrays." Because of this similarity, the phrase "virtual hybridization" is used to describe this approach. Protein sequences generated from the gene sequences were randomly chosen to serve as "probes" for the virtual arrays, and virtual hybridization for each GN plasmid was achieved using BLASTp. Each resulting intensity matrix was used to generate a distance matrix from which an initial tree was constructed. Relationships were refined for several clusters by identifying conserved proteins within a cluster. Multiple-sequence alignment was applied to the concatenated conserved proteins, and maximum likelihood was used to generate relationships from the results of the alignment. While it is not possible to prove that the genetic relationships among the 527 GN bacterial plasmids obtained in this study are correct, replication of identical results produced in a separate study for a small group of IncA/C plasmids provides evidence that the approach used can correctly predict genetic relationships. In addition, results obtained for clusters of Borrelia plasmids are consistent with the expected exclusivity for plasmids from this genus. Finally, the 527-plasmid tree was used to study the distribution of four common antibiotic resistance genes.     

A new series of trpE vectors that enable high expression of nonfusion proteins in bacteria.

Expression of recombinant proteins in bacteria has facilitated the characterization of many gene products. However, the biochemical characterization of recombinant proteins is limited since the bacterially expressed proteins are often synthesized as fusion polypeptides. The presence of bacterial sequences in fusion proteins further limits the use of these proteins for generating antibodies since the bacterial sequences are also antigenic. We describe two new bacterial expression vectors based on the pATH series of plasmids. These vectors were made by precisely deleting all of the trpE coding sequences found in pATH. The new vectors have enabled us to express eukaryotic genes as nonfusion polypeptides. These altered plasmids can be used to insert any DNA sequence of interest through a multiple cloning site located just 3' of an ATG start codon. Protein expression is still under the control of the trp operon and is carried out at great efficiency when the bacteria are tryptophan deprived. Studies presented here test the expression system with neurofilament subunits, NF-L and NF-H. Large amounts of recombinant nonfusion proteins were produced. Also, a time course of induction shows that the production of the nonfusion proteins was under the control of the trp operon which is readily inducible after tryptophan starvation and addition of indoleacrylic acid. These vectors may be useful for the overexpression of many proteins in a form closely approximating their native state.     

Digoxigenin-labeled RNA probes for untranslated regions enable the isoform-specific gene expression analysis of myosin heavy chains in whole-mount in situ hybridization

Myosin heavy chains (MyHCs), which are encoded by myosin heavy chain (Myh) genes, are the most abundant proteins in myofiber. Among the 11 sarcomeric Myh isoform genes in the mammalian genome, seven are mainly expressed in skeletal muscle. Myh genes/MyHC proteins share a common role as force producing units with highly conserved sequences, but have distinct spatio-temporal expression patterns. As such, the expression patterns of Myh genes/MyHC proteins are considered as molecular signatures of specific fiber types or the regenerative status of mammalian skeletal muscles. Immunohistochemistry is widely used for identifying MyHC expression patterns; however, this method is costly and is not ideal for whole-mount samples, such as embryos. In situ hybridization (ISH) is another versatile method for the analysis of gene expression, but is not commonly applied for Myh genes, partly because of the highly homologous sequences of Myh genes. Here we demonstrate that an ISH analysis with the untranslated region (UTR) sequence of Myh genes is cost-effective and specific method for analyzing the Myh gene expression in whole-mount samples. Digoxigenin (DIG)-labeled antisense probes for UTR sequences, but not for protein coding sequences, specifically detected the expression patterns of respective Myh isoform genes in both embryo and adult skeletal muscle tissues. UTR probes also revealed the isoform gene-specific polarized localization of Myh mRNAs in embryonic myofibers, which implied a novel mRNA distribution mechanism. Our data suggested that the DIG-labeled UTR probe is a cost-effective and versatile method to specifically detect skeletal muscle Myh genes in a whole-mount analysis.     

Nucleotide sequences of cloned cDNA fragments specific for six Xenopus laevis ribosomal proteins

We have previously constructed and selected six recombinant plasmids containing cDNA sequences specific for different ribosomal proteins of Xenopus laevis (Bozzoni et al., 1981). DNA cloned in these plasmids have been isolated and sequenced. Amino acid sequences of the corresponding portions of the proteins have been derived from DNA sequences; they are arginine- and lysine-rich as expected for ribosomal proteins. One of the cDNA sequences has an open reading frame also on the strand complementary to the one coding for the ribosomal protein; this fragment has inverted repeats twenty nucleotides long at the two ends. The codon usage for the six sequences appears to be non-random with some differences among the ribosomal proteins analysed.     

Use of green fluorescent protein/Flp recombinase fusion protein and flow cytometric sorting to enrich for cells undergoing Flp-mediated recombination

Flp recombinase has been used extensively for in vivo manipulation of eukaryotic DNA at specific sequences designated as FRT sites. We developed a method to use Flp-mediated recombination without the need for drug resistance or metabolic selection of cells in which recombination has occurred. We generated expression plasmids directing expression of fusion proteins consisting of Flp recombinase and green fluorescent protein (GFP) coding sequences. When the plasmids were introduced into K562 cells containing Flp recombinase substrates and transfected cells were selected for by flow cytometric sorting, GFP-positive cells were enriched 5- to 30-fold for Flp-mediated recombination events compared with unsorted cells. These studies demonstrate the usefulness of GFP/Flp recombinase fusion proteins to manipulate chromosomal DNA in vivo without requiring drug resistance or metabolic marker genes.     

Glucose oxidase from Aspergillus niger. Cloning, gene sequence, secretion from Saccharomyces cerevisiae and kinetic analysis of a yeast-derived enzyme

The gene for Aspergillus niger glucose oxidase (EC 1.1.3.4) has been cloned from both cDNA and genomic libraries using oligonucleotide probes derived from the amino acid sequences of peptide fragments of the enzyme. The mature enzyme consists of 583 amino acids and is preceded by a 22-amino acid presequence. No intervening sequences are found within the coding region. The enzyme contains 3 cysteine residues and 8 potential sites for N-linked glycosylation. The protein shows 26% identity with alcohol oxidase of Hansenuela polymorpha, and the N terminus has a sequence homologous with the AMP-binding region of other flavoenzymes such as p-hydroxybenzoate hydroxylase and glutathione reductase. Recombinant yeast expression plasmids have been constructed containing a hybrid yeast alcohol dehydrogenase II-glyceraldehyde-3-phosphate dehydrogenase promoter, either the yeast alpha-factor pheromone leader or the glucose oxidase presequence, and the mature glucose oxidase coding sequence. When transformed into yeast, these plasmids direct the synthesis and secretion of between 75 and 400 micrograms/ml of active glucose oxidase. Analysis of the yeast-derived enzymes shows that they are of comparable specific activity and have more extensive N-linked glycosylation than the A. niger protein.     

Comparison of class I (H-2) gene sequences. Derivation of unique probes for members of this multigene family

The genes for the classical transplantation antigens are unique in that they belong to a multigene family of which each member is represented by a large number of alleles. Since all of these genes are highly related in sequence, it has been difficult to study the expression of individual members of this complex gene family. Based upon our initial suggestion that the 3' noncoding regions of these genes may be useful in identifying mRNA molecules transcribed from different loci, we have compared a large number of sequences from different inbred mouse strains and have been able to assign each of these sequences without ambiguity into distinct allelic series. Such accurate assignment has afforded the opportunity to compare the coding regions of these highly homologous genes and has led to the identification of sequences which are apparently unique to specific genes in the family. Synthetic oligonucleotides corresponding to each of the locus-specific unique regions have been used successfully to type a panel of cDNA sequences, as well as to quantitate the relative amounts of mRNA transcribed from distinct loci. The availability of these specific coding probes will allow the analysis of individual genes and their specific expression without interference from other highly homologous sequences in this multigene family.     

Number and organization of actin-related sequences in the mouse genome

Recombinant plasmids containing cDNA sequences complementary to the two mouse striated-muscle actin messenger RNAs (pAF81, pAM91) and to a non-muscle actin mRNA (pAL41) have been used to examine the number and organization of actin-related sequences in the mouse genome. A large number (greater than 20) of actin-related sequences are detected on Southern blots of restricted mouse DNA, the majority of which hybridize to both the 5' and 3' ends of the actin-coding sequence, even under conditions revealing only sequences greater than 80% homologous to the actin cDNA probes. More stringent washing of these blots indicates that the two striated muscle actins are each encoded by single genes, and that a non-muscle (beta or gamma) actin cDNA detects one homologous and two closely related sequences in mouse DNA. The segregation of the two striated-muscle actin genes in recombinant inbred mouse strains shows that these genes are not closely linked (greater than 1 centimorgan), and that the skeletal muscle actin gene is not linked to a non-muscle actin gene. Screening a bank of mouse genomic DNA, cloned in Charon 4A, indicates that the number of actin-related sequences in the mouse genome is much higher than 20. In particular, five phages have been isolated representing part of a sub-family of 20 to 50 similar but non-identical sequences, only weakly homologous to actin cDNA probes (probably a family of actin pseudogenes), which are the result of a recent amplification of a greater than 17 X 10(3) base region of mouse DNA.     

Regulation of muscle gene expression: The accumulation of messenger RNAs coding for muscle-specific proteins during myogenesis in a mouse cell line

The expression of RNA sequences coding for myofibrillar proteins has been followed during terminal differentiation in a mouse skeletal muscle cell line. Cloned complementary DNA probes hybridizing with the actins, skeletal muscle α-actin, myosin heavy chain and the myosin alkali light chains were employed in Northern blotting experiments with total cellular poly (A)-containing RNA extracted from the cultures at different times after plating. At the same times, parallel cultures were pulse-labelled with [³⁵S]methionine and the pattern of newly synthesized proteins was analysed by two-dimensional gel electrophoresis. Synthesis of skeletal muscle α-actin and of the myosin alkali light chains (LC_lemb, LC₁, LC₃) was not detectable in dividing myoblast cultures. From the onset of cell fusion, the synthesis of myosin heavy chain, LC_lemb and α-actin increases with similar kinetics. Synthesis of LC₃ (and trace amounts of LC_1F) is detectable and subsequently increases at later stages of myotube formation. The corresponding messenger RNAs coding for myosin heavy chain and skeletal muscle α-actin are first detectable immediately before the initiation of myofibrillar protein synthesis. mRNAs coding for the non-muscle actins are accumulated in myoblasts and diminish after cell fusion. Comparisons between muscle mRNAs depend on the relative sensitivities of the different probes, reflecting mainly their homology with the isoform of the actin or myosin multigene family expressed. Quantitative analysis of Northern blots gives an estimated increase in skeletal muscle α-actin mRNA, with an homologous probe, of at least 130-fold with a minimum level of detection of 40 to 80 molecules per cell. Accumulation of this species and of the myosin heavy chain mRNA follows similar kinetics. mRNA coding for LC₃, the principal myosin light chain detected with the probe, appears to accumulate to a lesser extent initially, paralleling synthesis of the corresponding protein. These results using cloned probes demonstrate a close temporal correlation between muscle mRNA accumulation and protein synthesis during terminal myogenesis in this muscle line.     

Rolling-circle replication of bacterial plasmids.

Many bacterial plasmids replicate by a rolling-circle (RC) mechanism. Their replication properties have many similarities to as well as significant differences from those of single-stranded DNA (ssDNA) coliphages, which also replicate by an RC mechanism. Studies on a large number of RC plasmids have revealed that they fall into several families based on homology in their initiator proteins and leading-strand origins. The leading-strand origins contain distinct sequences that are required for binding and nicking by the Rep proteins. Leading-strand origins also contain domains that are required for the initiation and termination of replication. RC plasmids generate ssDNA intermediates during replication, since their lagging-strand synthesis does not usually initiate until the leading strand has been almost fully synthesized. The leading- and lagging-strand origins are distinct, and the displaced leading-strand DNA is converted to the double-stranded form by using solely the host proteins. The Rep proteins encoded by RC plasmids contain specific domains that are involved in their origin binding and nicking activities. The replication and copy number of RC plasmids, in general, are regulated at the level of synthesis of their Rep proteins, which are usually rate limiting for replication. Some RC Rep proteins are known to be inactivated after supporting one round of replication. A number of in vitro replication systems have been developed for RC plasmids and have provided insight into the mechanism of plasmid RC replication.     

High-level expression of the simian virus 40 genes LP1, VP1 and VP2 as fusion proteins in Escherichia coli

The complete sequences of the SV40 agnogene (LP1) and the genes coding for the capsid proteins VP1 and VP2 have been cloned into Escherichia coli expression plasmids. High levels of expression were obtained when the SV40 genes were inserted into the coding sequence of the influenza virus NS1 gene, which has previously been expressed in E. coli. The NS1A-LP1 and NS1A-VP2 chimeric proteins consist of the 81 N-terminal residues of NS1 (designated as peptide NS1A) fused to the complete sequence of the corresponding SV40 protein. The NS1A-VP1 chimera consists of NS1A followed by a linker of nine arbitrary residues and the complete sequence of the SV40 major capsid protein. The observed levels of expression vary considerably among the three chimeric proteins, ranging from approx. 70 micrograms/ml in the case of NS1A-LP1 to approx. 5 micrograms/ml in the case of NS1A-VP2. Cyanogen bromide cleavage of the NS1A-LP1 fusion protein produces fragments with Mrs expected for isolated NS1A and LP1 peptides. A plasmid has also been constructed which expresses the NS1A peptide in high yield.     

Structural and functional organization of ColE2 and ColE3 replicons

Summary The complete nucleotide sequences of the 1.5 kb regions of ColE2 and ColE3 plasmids containing the segments sufficient for autonomous replication have been determined. They are quite homologous (greater than 90%), indicating that these two plasmids share common mechanisms of initiation of replication and its regulation. An open reading frame with a coding capacity for a protein of about 300 amino acids is present in both ColE2 and ColE3 and it actually specifies the Rep (for replication) protein, which is the plasmid specific trans-acting factor required for autonomous replication. The amino acid sequences of the Rep proteins of ColE2 and ColE3 are quite homologous (greater than 90%). The cis-acting sites (origins) where replication initiates in the presence of the trans-acting factors consist of 32 bp for ColE2 and 33 bp for ColE3. They are the smallest of all the prokaryotic replication origins so far reported. They are nonhomologous only at two positions, one of which, a deletion of a single nucleotide in ColE2 (or an insertion in ColE3), determines the plasmid specificity in interaction of the origins with the Rep proteins. Both plasmids carry a region with an identical nucleotide sequence and the one in ColE2, the IncA region, has been shown to express incompatibility against both ColE2 and ColE3. These results indicate that these plasmids share a common IncA determinant. A possibility that a small antisense RNA is involved in copy number control and incompatibility (IncA function) was suggested.     

Synthesis of fusion proteins with multiple copies of an antigenic determinant of foot-and-mouth disease virus

A series of four expression plasmids coding for fusion proteins containing foot-and-mouth disease virus (FMDV) sequences was constructed. The fusion proteins contain a large part of beta-galactosidase from Escherichia coli preceded (N-terminal) by 1, 2, 4 or 8 repeats of the antigenic determinant of FMDV consisting of amino acids 137-162 of the capsid polypeptide VP1. All four fusion proteins were efficiently produced in E. coli host bacteria. Immunization of rabbits resulted in FMDV-specific, neutralizing antibodies, the response being dependent on the number of repeats. With enzyme-linked immunosorbent-assay techniques it was shown that the FMDV antigenic determinants are exposed on the surface of the fusion proteins under non-denaturing conditions.     

Two bovine genes for mitochondrial ADP/ATP translocase expressed differences in various tissues

Two different bovine cDNAs have been characterized that encode closely related homologues of the mitochondrial membrane carrier protein ADP/ATP translocase. One of them codes for the protein that has been characterized previously from bovine heart mitochondria, and the other codes for a protein that differs from it in 33 amino acids out of 297. Including the base substitutions required to bring about these changes in amino acid sequence, the coding regions of the cDNAs differ at 184 positions. In addition, they are extensively diverged in their 3' noncoding sequences, which differ greatly in both length and sequence, and these segments of the cDNAs have been used as hybridization probes to demonstrate that the expression of the two genes giving rise to the two proteins is very different in various bovine tissues. Expression of one gene predominates in heart muscle and that of the other in intestine. Hybridization experiments with digests of genomic DNA have shown the presence of numerous sequences related to the two cDNAs in both the bovine and human genomes. Some of these probably arise from pseudogenes, but three expressed genes have been detected in the human genome. The study of the regulation of the expression of these genes may help to illuminate the basis of tissue-specific human mitochondrial diseases which arise because of defects in mitochondrial enzymes only in the affected tissue and not in other tissues of the same individual.     

Construction and characterization of hybrids containing genes coding for proteins of the central part of bacteriophage T4 baseplate.

The central part (hub or plug) of bacteriophage T4 baseplate consist of several proteins which are present in only few copies per phage particle. The presence of these minor baseplate components was inferred from the genetic data but only some of them were identified as distinct proteins species by biochemical analysis. We have constructed a number of plasmids containing segments of bacteriophage T4 genome coding for baseplate proteins. The following genes were cloned into expression vectors: 54, 48, 29, 28, 27, 51, 26 and 25. The presence of a particular gene product was confirmed by in vivo complementation test. On the basis of these results we could more precisely localize the position of a particular gene on T4 phage genetic map. The hybrids contain sets of genes which make aggregation impossible, so bacteria harbouring these plasmids are convenient starting point for the purification of baseplate proteins.