Complete sequence of constant and 3' noncoding regions of an immunoglobulin mRNA using the dideoxynucleotide method of RNA sequencing

RT-based Sanger sequencing of RNAs containing complex RNA repetitive elements

Although next-generation sequencing (NGS) technologies have revolutionized our ability to sequence DNA with high-throughput, the chain termination-based Sanger sequencing method remains a widely used approach for DNA sequence analysis due to its simplicity, low cost and high accuracy. In particular, high accuracy makes Sanger sequencing the "gold standard" for sequence validation in basic research and clinical applications. During the early days of Sanger sequencing development, reverse transcriptase (RT)-based RNA sequencing was also explored and showed great promise, but the approach did not acquire popularity over time due to the limited processivity and low template unwinding capability of Avian Myeloblastosis Virus (AMV) RT, and other RT enzymes available at the time. RNA molecules have complex features, often containing repetitive sequences and stable secondary or tertiary structures. While these features are required for RNA biological function, they represent strong obstacles for retroviral RTs. Repetitive sequences and stable structures cause reverse transcription errors and premature primer extension stops, making chain termination-based methods unfeasible. MarathonRT is an ultra-processive RT encoded group II intron that can copy RNA molecules of any sequence and structure in a single cycle, making it an ideal RT enzyme for Sanger RNA sequencing. In this chapter, we upgrade the Sanger RNA sequencing method by replacing AMV RT with MarathonRT, providing a simple, robust method for direct RNA sequence analysis. The guidance for troubleshooting and further optimization are also provided.

Poliovirus infection enhances the formation of two ribonucleoprotein complexes at the 3' end of viral negative-strand RNA

To identify proteins involved in the formation of replication complexes at the 3' end of poliovirus negative-strand RNA, a combined in vitro biochemical and in vivo genetic approach was used. Five subgenomic cDNA constructs were generated to transcribe different negative-strand RNA fragments. In UV cross-linking assays, distinct differences in binding of proteins in extracts from poliovirus-infected and uninfected cells to virus-specific, radiolabeled transcripts were observed. Two proteins present in extracts from poliovirus-infected cells with approximate molecular masses of 36 and 38 kDa were shown to cross-link to the 3' end of poliovirus negative-strand RNA. Appearance of the 36- and 38-kDa proteins in UV cross-linking assays can be detected 3 to 3.5 h after infection, and cross-linking reaches maximum levels by 5 h after infection. The binding site for the 36-kDa protein overlaps with the computer-predicted loop b region of stem-loop I, the so-called cloverleaf structure, and the RNA sequence of this region is required for efficient binding. Transfection of full-length, positive-sense RNA containing a five-nucleotide substitution (positions 20 to 25) in the loop b region of stem-loop I into tissue culture cells yielded only viral isolates with a reversion at position 24 (U-->C). This finding demonstrates that the wild-type cytidine residue at position 24 is essential for virus replication. RNA binding studies with transcripts corresponding to the 3' end of negative-strand RNA suggest that complex formation with the 36-kDa protein plays an essential role during the viral life cycle.

Minimum internal ribosome entry site required for poliovirus infectivity

Translation initiation by internal ribosome binding is a recently discovered mechanism of eukaryotic viral and cellular protein synthesis in which ribosome subunits interact with the mRNAs at internal sites in the 5' untranslated RNA sequences and not with the 5' methylguanosine cap structure present at the extreme 5' ends of mRNA molecules. Uncapped poliovirus mRNAs harbor internal ribosome entry sites (IRES) in their long and highly structured 5' noncoding regions. Such IRES sequences are required for viral protein synthesis. In this study, a novel poliovirus was isolated whose genomic RNA contains two gross deletions removing approximately 100 nucleotides from the predicted IRES sequences within the 5' noncoding region. The deletions originated from previously in vivo-selected viral revertants displaying non-temperature-sensitive phenotypes. Each revertant had a different predicted stem-loop structure within the 5' noncoding region of their genomic RNAs deleted. The mutant poliovirus (Se1-5NC-delta DG) described in this study contains both stem-loop deletions in a single RNA genome, thereby creating a minimum IRES. Se1-5NC-delta DG exhibited slow growth and a pinpoint plaque phenotype following infection of HeLa cells, delayed onset of protein synthesis in vivo, and defective initiation during in vitro translation of the mutated poliovirus mRNAs. Interestingly, the peak levels of viral RNA synthesis in cells infected with Se1-5NC-delta DG occurred at slightly later times in infection than those achieved by wild-type poliovirus, but these mutant virus RNAs accumulated in the host cells during the late phases of virus infection. UV cross-linking assays with the 5' noncoding regions of wild-type and mutated RNAs were carried out in cytoplasmic extracts from HeLa cells and neuronal cells and in reticulocyte lysates to identify the cellular factors that interact with the putative IRES elements. The cellular proteins that were cross-linked to the minimum IRES may represent factors playing an essential role in internal translation initiation of poliovirus mRNAs.

Expression of immunoglobulin kappa and lambda chains in mink

The ratio of kappa and lambda chains of immunoglobulins varies significantly from one species to another. It has previously been thought that lambda was only type expressed in mink. We tested mink immunoglobulin light chains using two monoclonal antibodies G80 and G88. It has been shown that G80 and G88 specifically recognize two antigenically different subpopulations of the light chains. Immunochemical analysis of these subpopulations separated by affinity chromatography suggested that they represent lambda and kappa types of light chains, respectively. Screening of a mink cDNA library with monoclonal antibody G88 resulted in the isolation of clone pIGK-1 containing kappa chain-encoding sequence. The cDNA insert of pIGK-1 included most of the V segment, as well as the J, C and 3' untranslated sequences. Mink V kappa sequence shown the highest homology with the human V kappa II subgroup genes (76-79%). Mink C kappa sequence was 53-63% homologous to C kappa of other species. The striking feature of mink C kappa chain is the presence of glutamine in the C-terminal position. Southern blot analysis suggested that mink haploid genome has one C kappa gene and multiple V kappa genes. The kappa:lambda chain ratio in the 12 minks studied was, on the average, 46:54. The same ratio was observed for the kappa- and lambda-producing cells in the mesenteric lymph nodes. The five previously identified mink light chain allotypes were assigned to the lambda chains, thereby confirming that lambda chains in this species are additionally subdivided into several subtypes.

Serological and molecular characterization of mouse anti-idiotypic monoclonal antibodies elicited with the syngeneic anti-HLA-A2,28 monoclonal antibody CR11-351

The molecular basis of the differential specificity of seven mouse anti-id mAb elicited with the syngeneic anti-HLA-A2,28 mAb CR11-351 was analyzed by comparing their specificity with their heavy and light chain variable region sequences. Of the six mAb recognizing idiotopes within the antigen combining site of mAb CR11-351, mAb T10-352, T10-440 and T10-505 recognize the same (or spatially close) idiotope(s) since they cross-inhibit each other in their binding to mAb CR11-351 and elicit syngeneic anti-anti-id antibodies with similar specificity. On the other hand, mAb T10-421, T10-649 and T10-938 appear to recognize spatially close but distinct idiotopes since they cross-inhibit each other, but elicit anti-anti-id antibodies which inhibit only the binding of the respective immunizing anti-id mAb to mAb CR11-351. mAb T8-203 is the only anti-id mAb which recognizes an idiotope outside the antigen combining site of mAb CR11-351 since it does not inhibit the binding of the latter to target cells and binds to mAb CR11-351 coated B lymphoid cells. In addition, mAb T8-203 defines an idiotope which is shared by seven anti-HLA mAb, while the remaining six anti-id mAb recognize idiotopes which are not detectable on the panel of anti-HLA mAb. mAb T10-352, T10-440 and T10-505 are highly homologous in their VH and VL regions and in their V(D)J junctions suggesting that they may be clonally related. On the other hand, mAb T8-203, T10-649 and T10-938 share some degree of homology in their VH region as all of them use J558 VH genes but differ considerably in their VL regions. Finally, mAb T10-421 is the most unrelated mAb as it utilizes VH, D, JH, VK and JK gene segments different from those of all the other anti-id mAb. These findings indicate that in the HLA-A antigenic system defined by mAb CR11-351 the main mechanism underlying the differential target specificity of syngeneic anti-id mAb is the combinatorial diversity together with the differential pairing of heavy and light chains.

The gene and the RNA for the precursor to the plastid-located glycerol-3-phosphate acyltransferase of Arabidopsis thaliana

The gene and the RNA from Arabidopsis thaliana for the plastid-located glycerol-3-phosphate acyltransferase (GPAT; EC 2.3.1.15) and their encoded product have been studied. The gene (designated ATS1) was isolated by screening a lambda DASH genomic library for cross-hybridization with a radiolabeled probe prepared from cDNA for GPAT from squash. cDNA clones representing the mRNA were isolated by screening a lambda ZAPII cDNA library for hybridization with a radiolabeled probe prepared from a DNA fragment of ATS1. The nucleotide sequences of the gene and the cDNA were determined, and the 5' end of the RNA was mapped by primer extension. Sequences similar to the TATA box, polyadenylation sequences and intron-splicing sequences were found at the expected locations. The pre-mRNA was 3288 nucleotides long and contained 5' and 3'-untranslated sequences of 57 and 442 nucleotides, respectively. The coding sequence of 1377 nucleotides was interrupted by 11 introns of 1412 nucleotides in total and the 3'-untranslated sequence contained another intron of 94 nucleotides. The open-reading frame encoded a polypeptide of 459 amino acid residues, the amino acid sequence of which was highly homologous to those of precursors to plastid-located GPATs from squash and pea. The enzymatic activity of a gene product that was over-produced in Escherichia coli confirmed the identity of the gene.

The general amino acid control regulates MET4, which encodes a methionine-pathway-specific transcriptional activator of Saccharomyces cerevisiae

A met4 mutant of Saccharomyces cerevisiae was unable to transcribe a number of genes encoding enzymes of the methionine biosynthetic pathway. The sequence of the cloned MET4 gene allowed the previously sequenced flanking LEU4 and POL1 genes to be linked to MET4 into a 10,327 bp contiguous region of chromosome XIV. From the sequence and mapping of the transcriptional start points, MET4 is predicted to encode a protein of 634 amino acids (as opposed to 666 amino acids published by others) with a leucine zipper domain at the C-terminus, preceded by both acidic and basic regions. Thus, MET4 belongs to the family of basic leucine zipper trans-activator proteins. Disruption of MET4 resulted in methionine auxotrophy with no other phenotype. Transcriptional studies showed that MET4 was regulated by the general amino acid control and hence by another bZIP protein encoded by GCN4. GCN4 binding sequences are present between the divergently transcribed MET4 and LEU4 genes. Over-expression of MET4 resulted in leaky expression from the otherwise tightly regulated MET3 promoter under its control. The presence of consensus sequences for other potential regulatory elements in the MET4 promoter suggests a complex regulation of this gene.

Molecular analysis of anti-idiotypic monoclonal antibodies in the HLA-DR antigenic system

The structural organization of anti-idiotypic (id) antibodies has been investigated mostly in haptenic systems. No information is available about the structural characteristics of anti-id antibodies in major histocompatibility complex (MHC) antigenic systems, although these data may contribute to our understanding of the molecular basis of their functional role in the immune response. Therefore, we have determined the nucleotide and derived amino acid sequence of the VH and VL regions of the anti-id monoclonal antibodies (mAb) F5-444, F5-830, F5-963, F5-1126, F5-1336 and F5-1419, which had been elicited with the syngeneic anti-HLA-DR1, 4, w14, w8, 9 mAb AC1.59. The six anti-id mAb are heterogenous in their VH and VL region gene usage. This structural heterogeneity is not correlated with their target specificity and with their ability to elicit anti-HLA-DR antibodies. The latter characteristic is markedly influenced by a limited number of amino acid substitutions, since mAb F5-444, which induces anti-HLA-DR antibodies, differs only in two residues in complementarity-determining regions and in five residues in framework regions from mAb F5-1126, which does not induce anti-HLA-DR antibodies. The heterogeneity in VH and VL region gene usage by the six anti-id mAb in the HLA-DR system is at variance with the restricted VH and VL region gene usage by syngeneic anti-id mAb in several haptenic systems. Furthermore, at variance with haptenic systems, the primary structure of the D segments of the anti-id mAb is not correlated with their ability to induce anti-HLA-DR antibodies. On the other hand, the frequency of D-D fusion events underlying the derivation of the D segments of the six anti-id mAb in the HLA-DR system and their average length are similar to those found in anti-id mAb in haptenic systems. In addition, like in the latter systems, somatic mutations appear to contribute to the generation of diversity of anti-id mAb in the HLA-DR system.

Comparison of the sequence and structure of transcription factor IIIA from Bufo americanus and Rana pipiens

Amino acid (aa) sequences of transcription factor IIIA (TFIIIA) from the toad, Bufo americanus, and the grass frog, Rana pipiens, were determined by cDNA cloning and DNA sequencing. The 3'-untranslated regions of the cDNAs reveal that the TFIIIA gene polyadenylation signal is ATTAAA, rather than the conventional AATAAA. The B. americanus and R. pipiens proteins share about 60% aa sequence homology with each other and with Xenopus laevis TFIIIA. Although these results indicate that TFIIIA has more sequence variation than other DNA-binding proteins, a number of conserved features are evident and of likely functional significance. These include potential guanine nucleotide-binding sites at arginines in zinc fingers (ZnF) II, V, and IX, acidic residues between metal-coordinating cysteines, and a basic region in the C-terminal tail possibly involved in transcription promotion. Sequence similarity also exists in an aa stretch bridging the ninth ZnF and C-terminal tail of both TFIIIA and the 5S RNA-binding protein, p43. DNase I protection analyses demonstrate that B. americanus and R. pipiens TFIIIA interact with the internal control region (ICR) of the Xenopus borealis 5S RNA-encoding gene (5S) in different manners: the B. americanus interaction is similar to X. laevis TFIIIA, protecting the entire 5S gene ICR (nt +96 to +43) from DNase I digestion, whereas the R. pipiens TFIIIA strongly protects the ICR from nt +96 up to +78 and less strongly from +78 to +43. Possibly accounting for the binding differences observed, R. pipiens and R. catesbeiana oocyte 5S RNAs (and by inference 5S genes) were found to contain a G or U at nt position 50 while B. americanus, X. laevis, and other eukaryotic 5S RNAs have an A in the analogous position (nt 53 in generalized eukaryotic structure).

Linker scanning mutagenesis of the internal ribosome entry site of poliovirus RNA

The initiation of cap-independent translation of poliovirus mRNA occurs as a result of ribosome entry at an internal site(s) within the 5' noncoding region. A series of linker scanning mutations was constructed to define the genetic determinants of RNA-protein interactions that lead to high-fidelity translation of this unusual viral mRNA. The mutations are located within two distinct stem-loop structures in the 5' noncoding region of poliovirus RNA that constitute a major portion of a putative internal ribosome entry site. On the basis of our data derived from genetic and biochemical assays, the stability of one of the stem-loop structures appears to be essential for translation initiation via internal binding of ribosomes. However, the second stem-loop structure may function in a manner that requires base pairing and proper spacing between specific nucleotide sequences. By employing RNA electrophoretic mobility shift assays, an RNA-protein interaction was detected for this latter stem-loop structure that does not occur in RNAs containing mutations which perturb the predicted hairpin structure. Analysis of in vivo-selected virus revertants, in combination with mobility shift assays, suggests that extensive genetic rearrangement can lead to restoration of 5' noncoding region functions, possibly by the repositioning of specific RNA sequence or structure motifs.

High frequency of single-base transitions and extreme frequency of precise multiple-base reversion mutations in poliovirus

We employed independent clones of a temperature-sensitive mutant of type 1 poliovirus, 3AB-310/4, to quantitate the frequency of specific U----C transitions at nucleotide 5310, within the genomic region encoding polypeptide 3AB, which is involved in the initiation of RNA replication. Only this U----C base substitution restores the wild-type phenotypic ability to form plaques at 39 degrees C; the other two base substitutions at this site are lethal. The observed frequency of this specific transition averaged 2 x 10(-5), and all revertant viruses forming plaques at 39 degrees C contained the expected cytidine at nucleotide 5310. Incredibly, only 3 of 10 revertants exhibited this one specific U----C transition whereas 7 of 10 exhibited this same transition plus four additional base substitutions that precisely reverted temperature-sensitive 3AB-310/4 to wild-type poliovirus sequence (these latter four mutations had been introduced into 3AB-310/4 as silent third base mutations to provide new restriction sites in infectious cDNAs). No other mutations were detected in this polypeptide 3AB domain in either the single-base or the precise 5-base revertants. No intermediates were seen; all revertants exhibited either the single U----C transition at nucleotide 5310 or the same transition plus four precise reversions to the wild-type sequence at sites 8, 11, 43, and 46 bases distant from nucleotide 5310. Similar results were obtained after transfection of cDNA-derived transcripts. We discuss possible mechanisms for our data. These include (but may not be limited to) error-prone polymerase activity, sequential RNA recombination events joining independent mutations, or some unusual RNA editing process.

Immunoglobulin V regions and epitope mapping of a murine monoclonal antibody against p24 core protein of HIV-1

The nucleotide sequence of a murine monoclonal antibody (CB-mab-p24/13-5) against p24 core protein of the human immunodeficiency virus (HIV-1) was determined for variable regions of the heavy and light chain, respectively. Genetic elements encoding the VDJH- and VJL-regions of the antibody were generated from RNA by the polymerase chain reaction, cloned into the vector pICEM 19R and sequenced. Synthetic peptides, 10 amino acids overlapping served for the localization of the epitope. The residues 152-156 within the p24 sequence contain the epitope.

V genes of oxazolone antibodies in 10 strains of mice

One pair of V genes (V kappa 45.1 and V11) code for a great portion of phenyloxazolone (anti-phOx) antibodies in 10 strains of mice. This combination replaces the first-known major combination VHOx1-V kappa Ox1 in some strains, and is important in most strains. C57BL/10 and SJL mice have an additional subset of antibodies encoded by genes V kappa 45.1 and V13 (a relative of V11). All three genes involved (V kappa 45.1, V11 and V13) have "allelic" variation. Four alleles of V11 were found, one in Igh haplotypes a, c and g, the second in haplotypes d, j and n, the third in b, and the fourth in f. The most distant alleles d, j, n and f had 10 nucleotide differences out of 429 determined (97.7% homology). Only one allele of the V13 gene was found from anti-phOx hybridomas but two others have been published. Three alleles of the V kappa 45.1 gene were found; one in NZB mice (Ig kappa haplotype b) another in CE (haplotype f), and the third in eight strains including representatives of three Ig kappa haplotypes (a, c and e). The three alleles had greater than 99.0% homology. The V11 and V13 genes that code for anti-phOx antibodies in C57BL/10 and SJL mice were different from the related genes found from the C57BL/10 germ line. C57BL/10 mice must have a chromosome bearing two V11 and two V13 genes. RF mice were found to have two V11 genes, and both code for anti-phOx antibodies. Our data show that the majority of antibodies in the anti-phOx response are encoded by the same restricted collection of V genes in most mouse strains. Antibody responses appear to be no less heritable than other functions of the body.

Role for the P4 amino acid residue in substrate utilization by the poliovirus 3CD proteinase

Amino acid insertions or substitutions were introduced into the poliovirus P1 capsid precursor at locations proximal to the two known Q-G cleavage sites to examine the role of the P4 residue in substrate processing by proteinase 3CD. Analysis of the processing profile of P1 precursors containing four-amino-acid insertions into the carboxy terminus of VP3 or a single-amino-acid substitution at the P4 position of the VP3-VP1 cleavage site demonstrates that substitution of the alanine residue in the P4 position of the VP3-VP1 cleavage site significantly affects cleavage at that site by proteinase 3CD. A single-amino-acid substitution at the P4 position of the VP0-VP3 cleavage site, on the other hand, has only a slight effect on 3CD-mediated processing at this cleavage site. Finally, analysis of six amino acid insertion mutations containing Q-G amino acid pairs demonstrates that the in vitro and in vivo selection of a cleavage site from two adjacent Q-G amino acid pairs depends on the presence of an alanine in the P4 position of the cleaved site. Our data provide genetic and biochemical evidence that the alanine residue in the P4 position of the VP3-VP1 cleavage site is a required substrate determinant for the recognition and cleavage of that site by proteinase 3CD and suggest that the P4 alanine residue may be specifically recognized by proteinase 3CD.

Immunoglobulin VH and VK genes of the BALB/c anti-foot-and-mouth disease virus (O1) VP1 response: cloning, characterization and transgenic mice

Hybridomas producing monoclonal antibodies of different isotypes were isolated from BALB/c antibody responses to the capsid protein VP1 of the foot-and-mouth disease virus (FMDV) strain O1. According to antigen binding measured by ELISA a weak-binding (81D10, IgM) and a strong-binding antibody (113C12, IgG2a) were selected. As RNA sequencing of productive immunoglobulin VH and VK genes turned out, both chains of the weak-binding antibody (81D10) are encoded by germline (i.e. not mutated) genes whereas the gene encoding the strong-binding antibody (113C12) k chain is mutated at several sites. Therefore, rearranged VH and VK genes of 81D10 were cloned, expressed in immunoglobulin non-producing plasmacytoma cells, and mice transgenic for the 81D10 k gene were produced. These mice provide a first step in the development of a transgenic mouse model for genetical investigations in the affinity maturation of anti-viral immunoglobulin variable genes.

Germ-line origin of functional idiotypic interactions: identification of two idiotypically connected, natural antibodies that are encoded by germ-line gene elements

Two monoclonal, natural IgM antibodies derived from normal BALB/c mice were selected on the basis of being idiotypically complementary and functionally connected. Nucleotide sequence analysis of their respective heavy and light chain V regions showed that both of the clones expressed VH, D, JH, VL and JL gene segments of germ-line origin. Furthermore, none of the clones displayed N-sequence additions. These data suggest a germ-line origin of a functional idiotypic network and confirm a minimized contribution of somatic diversification through template-independent addition of N-nucleotides in neonatal B cell repertoires.

Cloning, nucleotide sequence, and regulation of MET14, the gene encoding the APS kinase of Saccharomyces cerevisiae

The MET14 gene of Saccharomyces cerevisiae, encoding APS kinase (ATP:adenylylsulfate-3'-phosphotransferase, EC 2.7.1.25), has been cloned. The nucleotide sequence predicts a protein of 202 amino acids with a molecular mass of 23,060 dalton. Translational fusions of MET14 with the beta-galactosidase gene (lacZ) of Escherichia coli confirmed the results of primer extension and Northern blot analyses indicating that the ca. 0.7 kb mRNA is transcriptionally repressed by the presence of methionine in the growth medium. By primer extension the MET14 transcripts were found to start between positions -25 and -45 upstream of the initiator codon. Located upstream of the MET14 gene is a perfect match (positions -222 to -229) with the previously proposed methionine-specific upstream activating sequence (UASMet). This is the same as the consensus sequence of the Centromere DNA Element I (CDEI) that binds the Centromere Promoter Factor I (CPFI) and of two regulatory elements of the PHO5 gene to which the yeast protein PHO4 binds. The human oncogenic protein c-Myc also has the same recognition sequence. Furthermore, in the 270 bp upstream of the MET14 coding region there are several matches with a methionine-specific upstream negative (URSMet) control element. The significance of these sequences was investigated using different upstream deletion mutations of the MET14 gene which were fused to the lacZ gene of E. coli and chromosomally integrated. We find that the methionine-specific UASMet and one of the URSMet lie in regions necessary for strong activation and weak repression of MET14 transcription, respectively. We propose that both types of control are exerted on MET14.

trans rescue of a mutant poliovirus RNA polymerase function

A series of three-nucleotide insertions was engineered into the P2 and P3 coding regions of the T7 expression plasmid pT7(tau)-PV1, which encodes a full-length copy of poliovirus type 1 (Mahoney) cDNA. When RNA derived in vitro from these mutated templates was used to transfect HeLa cells, viable virus mutants were recovered. One mutant, Sel-3D-18, which contained a single amino acid insertion in the 3Dpol coding region, was temperature sensitive for growth at 39 degrees C and showed defects in both RNA synthesis and P1 protein processing at the nonpermissive temperature. The RNA replication defect in Se1-3D-18 was identified at the level of RNA chain elongation. A highly specific and sensitive method was developed for analyzing the ability of mutant RNA templates to replicate in the presence or absence of helper functions provided in trans. This approach was used to demonstrate that RNA synthesis in Se1-3D-18 can be rescued by helper functions provided in trans.

Insertion of part of an intron into the 5' untranslated region of a Caenorhabditis elegans gene converts it into a trans-spliced gene

In nematodes, the RNA products of some genes are trans-spliced to a 22-nucleotide spliced leader (SL), while the RNA products of other genes are not. In Caenorhabditis elegans, there are two SLs, SL1 and SL2, donated by two distinct small nuclear ribonucleoprotein particles in a process functionally quite similar to nuclear intron removal. We demonstrate here that it is possible to convert a non-trans-spliced gene into a trans-spliced gene by placement of an intron missing only the 5' splice site into the 5' untranslated region. Stable transgenic strains were isolated expressing a gene in which 69 nucleotides of a vit-5 intron, including the 3' splice site, were inserted into the 5' untranslated region of a vit-2/vit-6 fusion gene. The RNA product of this gene was examined by primer extension and PCR amplification. Although the vit-2/vit-6 transgene product is not normally trans-spliced, the majority of transcripts from this altered gene were trans-spliced to SL1. We termed the region of a trans-spliced mRNA precursor between the 5' end and the first 3' splice site an "outron." Our results suggest that if a transcript begins with intronlike sequence followed by a 3' splice site, this alone may constitute an outron and be sufficient to demarcate a transcript as a trans-splice acceptor. These findings leave open the possibility that specific sequences are required to increase the efficiency of trans-splicing.

Insertion of part of an intron into the 5' untranslated region of a Caenorhabditis elegans gene converts it into a trans-spliced gene

In nematodes, the RNA products of some genes are trans-spliced to a 22-nucleotide spliced leader (SL), while the RNA products of other genes are not. In Caenorhabditis elegans, there are two SLs, SL1 and SL2, donated by two distinct small nuclear ribonucleoprotein particles in a process functionally quite similar to nuclear intron removal. We demonstrate here that it is possible to convert a non-trans-spliced gene into a trans-spliced gene by placement of an intron missing only the 5' splice site into the 5' untranslated region. Stable transgenic strains were isolated expressing a gene in which 69 nucleotides of a vit-5 intron, including the 3' splice site, were inserted into the 5' untranslated region of a vit-2/vit-6 fusion gene. The RNA product of this gene was examined by primer extension and PCR amplification. Although the vit-2/vit-6 transgene product is not normally trans-spliced, the majority of transcripts from this altered gene were trans-spliced to SL1. We termed the region of a trans-spliced mRNA precursor between the 5' end and the first 3' splice site an "outron." Our results suggest that if a transcript begins with intronlike sequence followed by a 3' splice site, this alone may constitute an outron and be sufficient to demarcate a transcript as a trans-splice acceptor. These findings leave open the possibility that specific sequences are required to increase the efficiency of trans-splicing.

In vitro assembly of infectious nucleocapsids of bacteriophage phi 6: formation of a recombinant double-stranded RNA virus

A system is described for assembling infectious bacteriophage phi 6 nucleocapsids in vitro. Procapsids encoded by cDNA copies of genomic segment L in Escherichia coli were used to package and replicate viral RNA segments. The resulting filled particles were shown to be capable of infecting host cell spheroplasts after incubation with purified nucleocapsid shell protein P8. The infected spheroplasts yielded infectious virions. A modified cDNA-derived RNA segment was inserted into virions by this method. The resulting infectious virions contained the same 4-base-pair deletion as the modified cDNA. These findings support the contention that the preformed procapsids are the "machine" that replicates the phi 6 genome, by showing that the cDNA-derived procapsids are competent to package and replicate RNA properly.

Variable region sequences of pathogenic anti-mouse red blood cell autoantibodies from autoimmune NZB mice

New Zealand Black (NZB) mice spontaneously develop a severe autoimmune hemolytic anemia due to the production of anti-mouse red blood cell (MRBC) autoantibodies. The contribution of variable region genes and somatic mutations in the pathogenicity of anti-MRBC autoantibodies was investigated by mRNA sequencing of eight NZB anti-MRBC monoclonal autoantibodies, among which five are capable of inducing anemia in BALB/c mice. Here we report that at least three VH gene families (J558, J606 and 3609) and five Vchi subgroups (V chi 8, 9, 19, 21 and 28), in combination with several D, JH and Jchi gene segments, encode anti-MRBC autoantibodies. Thus, the NZB anti-MRBC autoantibodies, whether pathogenic or not, are encoded by a large number of immunoglobulin gene elements and by members of known VH and Vchi gene families with preferential usage of VH gene families most distal to the D regions. The presence of several mutations in the JH gene segments of both IgM and IgG anti-MRBC autoantibodies, whether pathogenic or not, strongly suggests that their VH regions may be highly mutated and that the mechanism of somatic diversification might be important in the generation of anti-MRBC autoantibodies. Our results support the idea that anti-MRBC autoimmune responses are likely to be generated by an antigen-driven mechanism.

A mutant poliovirus containing a novel proteolytic cleavage site in VP3 is altered in viral maturation

A six-amino-acid insertion containing a Q-G amino acid pair was introduced into the carboxy terminus of the capsid protein VP3 (between residues 236 and 237). Transfection of monkey cells with full-length poliovirus cDNA containing the insertion described above yields a mutant virus (Sel-1C-02) in which cleavage occurs almost entirely at the inserted Q-G amino acid pair instead of at the wild-type VP3-VP1 cleavage site. Mutant Sel-1C-02 is delayed in the kinetics of virus production at 39 degrees C and exhibits a defect in VP0 cleavage into VP2 and VP4 at 39 degrees C. Sucrose gradient analysis of HeLa cell extracts prepared from cells infected by Sel-1C-02 at 39 degrees C shows an accumulation of fast-sedimenting replication-packaging complexes and a significant amount of uncleaved VP0 present in fractions containing mature virions. Our data provide in vivo evidence for the importance of determinants other than the conserved amino acid pair (Q-G) for recognition and cleavage of the P1 precursor by proteinase 3CD and show that an alteration in the carboxy terminus of VP3 or the amino terminus of VP1 affects the process of viral maturation.

Transcription of orthopoxvirus telomeres at late times during infection

The telomeres of orthopoxvirus DNAs consists largely of short repeated sequences organized into at least two separate sets. Although the sequence composition of the orthopoxvirus telomeres is highly conserved, these regions do not appear to encode any proteins. At late times during infection, the telomeres of vaccinia virus are transcribed. A promoter in the region between the two sets of repeats directs transcription towards the hairpin-loop end of the viral DNA. This promoter resembles the promoters of other poxvirus late genes, and directs the synthesis of RNAs whose structure is consistent with the presence of 5' poly(A) sequences typical of late RNAs. The lengths of these late transcripts suggest that some transcription extends through the hairpin-loop region. This might occur either when the genome is in a monomeric form or when the genome is in the concatemeric form of the DNA replication intermediate. The function of late transcription of the telomeres is unclear, but similar transcription of the telomeres of vaccinia virus, cowpox virus, and raccoonpox virus suggests that such transcription may have a role in viral replication.

RNA sequencing using fluorescent-labeled dideoxynucleotides and automated fluorescence detection

Although dideoxy terminated sequencing of RNA, using reverse transcriptase and oligodeoxynucleotide primers, is now a well established method, the accuracy is limited by sequence ambiguities due to unspecific chain termination events. A protocol is described which circumvents these ambiguities by using fluorescence labels tagged to dideoxynucleotides. Only chain terminations caused by dideoxynucleotides were detected while premature terminated cDNA's remain undetectable. In addition, the remaining multiple signals at nucleotide positions can be assigned to sequence heterogeneities within the RNA sequence to be determined.

A genetic locus in mutant poliovirus genomes involved in overproduction of RNA polymerase and 3C proteinase

A mutagenic oligonucleotide cassette was used to introduce single and tandem amino acid substitutions into the proteinase 3C coding region of an infectious poliovirus type 1 cDNA. The sites targeted for mutagenesis, residues 60, 61, and 66, are located within a putative helical loop structure which may be involved in substrate recognition by the enzyme. Fourteen viable 3C proteinase mutants were isolated. A Lys----Arg substitution at position 60 resulted in cold sensitivity for growth at 33 degrees. Replacement of Lys 60 with Ile, either singly or in combination with substitutions at position 61, resulted in viruses that produced three- to fivefold more 3D RNA polymerase than wild-type poliovirus. 3C-mediated processing of the remaining sites within the polyprotein was not noticeably affected. The overproduction of 3D is a consequence of more efficient processing of the carboxy-terminal Gln-Gly amino acid pair of 3C. Together with a previous report in which substitution of Val 54 with an Ala residue results in a poliovirus that produces decreased levels of 3D, these observations provide evidence that the putative loop region (residues 51-66) may be a functional domain involved in recognition of the carboxy-terminal Gln-Gly cleavage site of 3C.

Structure and transcription of the glycoprotein gene of attenuated HEP-Flury strain of rabies virus

The mRNA-encoding G protein of the attenuated HEP-Flury strain of rabies virus was sequenced by the cDNA cloning technique. The G-mRNA was composed of 2059 nucleotides, with the coding region located from the 28th to 1602nd nucleotide, and was capable of encoding a polypeptide of 524 amino acids. Although the coding region was highly homologous (90% or more) to that of ERA and PV strains, the 3' noncoding region of the HEP virus G-mRNA was longer than that reported for other strains by some 400 nucleotides. The extra sequence was homologous to the long G-L intergenic sequence of the PV viral genome. The HEP virus genome lacked the postulated polyadenylating signal (TG-AAAAAAAA) that should have been found just before the "long G-L intergenic region," which indicates that the long G-L intergenic region of the HEP virus is integrated into the preceding G gene, and is transcribed only as a portion of the G-mRNA molecule. In the ERA virus-infected cells, however, two species of G-mRNA (1.9 and 2.3 kb long) were produced. The longer G-mRNA also contained the sequence complementary to the long G-L intergenic region and the shorter one did not. These findings suggest that two different poly(A)-tailing signals (one is present just before and another at the end of the long G-L intergenic region) work toward terminating the transcription of the ERA virus G gene and that the longer G-mRNA is produced as a readthrough product.

RNA editing at a splicing site of NADH dehydrogenase subunit IV gene transcript in wheat mitochondria

Comparison between the sequence of the gene coding for the wheat mitochondrial NADH dehydrogenase subunit IV (nad4) and the cDNA sequence obtained by reverse transcription, using total wheat mtRNA as template, has shown the presence of a uridine residue, not encoded by the genomic sequence, at the exon2-exon3 junction of the spliced transcript. This U creates a non-encoded CUG leucine codon which is essential for maintaining the reading frame, as shown by the conservation of the amino acid sequence of the NAD4 protein in various species. The addition of a U or the specific post-transcriptional conversion of a C to a U could explain this phenomenon.

Rheumatoid factor autoantibody-binding site: a molecular analysis using monoclonal antibodies with dual anti-TNP and anti-IgG activities

Two out of five murine IgG3 anti-trinitrophenyl (TNP) monoclonal antibodies (mAb) obtained either by immunization with TNP-keyhole limpet hemocyanin (KLH) (CB1, CB5, CB6 and 4H10) or with dinitrophenyl-lipopolysaccharide (9A6), exhibited anti-IgG rheumatoid factor (RF) activity (CB6 and 4H10). The anti-IgG activity of these two anti-TNP RF was specifically inhibited by murine IgG as well as by the hapten TNP. In order to identify the structural basis for the anti-IgG activity, the nucleotide sequences encoding the VH and VL regions were determined. By comparing the V regions of the non-RF and RF anti-TNP mAb, it was found that one anti-TNP RF antibody, CB6, shares virtually identical VL and VH regions with two anti-TNP antibodies, CB1 and CB5, but markedly differs from these in the D region. Furthermore, the light chain framework region 2 (FR2) and FR3 of non-RF mAb, CB1, CB5 and 9A6, have amino acid sequences almost identical to those claimed for anti-IgG1 RF activity (Shlomchik et al., J. Exp. Med. 1986. 164: 407). Our findings suggest, at least in the case of CB6 mAb, the involvement of CDR, but not light chain FR residues, in IgG binding.

Molecular dissection of an antigen-specific immune response

Selection defines the repertoire of the primary response, and also which cells differentiate and enter the pool of the memory cells. Whereas the primary response is drawn from the germline repertoire, the memory response consists overwhelmingly of cells which have been hypermutated and selected to express receptors of high affinity. The accumulation of somatic mutations over time indicates that the activation of the memory cell by antigen also reactivates the hypermutation mechanism. Since the frequency of somatic mutations correlates with an increase in antibody affinity, an efficient selection operates not only on the primary B cells when first stimulated by antigen, but also on the memory cells after secondary or tertiary immunization.

Polymorphism of cytotoxic T-lymphocyte clones that recognize a defined nine-amino-acid immunodominant domain of lymphocytic choriomeningitis virus glycoprotein

To assess the heterogeneity of cytotoxic T lymphocytes (CTLs) directed against viral epitopes, we studied six class I major histocompatibility complex-restricted (H-2Db) CTL clones that recognize the same 9-amino-acid immunodominant epitope, amino acids 278 to 286 from envelope glycoprotein 2 (GP2) of lymphocytic choriomeningitis virus (LCMV). Using Southern blot analysis of beta-chain rearrangements, we found that each clone has a unique restriction pattern, providing evidence of the independent derivation of the clones and suggesting that the clones express different beta-chain sequences for their T-cell receptor. All these clones killed syngeneic target cells infected with strain Armstrong or WE of LCMV; however, two of the six clones failed to recognize target cells infected with the Pasteur strain of LCMV. Sequence analysis of LCMV Armstrong, WE, and Pasteur GP in the region of amino acids 272 to 293 demonstrated a single-amino-acid substitution at amino acid 278 in the region of the defined epitope in the Pasteur strain. Interestingly, one of the two CTL clones that failed to lyse LCMV Pasteur-infected target cells nevertheless efficiently and specifically killed uninfected target cells coated with the appropriate LCMV Pasteur peptide, while the other clone failed to do so. This indicated a dichotomy between processing of the synthesized protein initiated by infection and a peptide exogenously applied. Dose-response studies utilizing several peptides with substitutions in GP amino acid 278 indicate that CTL recognition occurs at the level of a single amino acid and suggest that this difference is likely recognized at the level of the T-cell receptor.

Isotype switching by a microinjected mu immunoglobulin heavy chain gene in transgenic mice

Immunization of transgenic mice carrying an immunoglobulin mu heavy chain resulted in a response dominated by expression of the transgene variable region. Unexpectedly, in a large proportion of the antibody produced by immunized mice, the transgene variable region was associated with IgG rather than IgM. This demonstrates that the transgene can undergo an isotype switch. Four transgenic founder lines all exhibited transgene isotype switching despite the likelihood of random chromosomal integration of the transgene. In addition one of the lines was analyzed by breeding studies and the transgene was found to be genetically unlinked to the immunoglobulin heavy chain (Igh) locus. These results indicate that a precise chromosomal location is not required for isotype switching and suggest the possibility that the isotype switching process can occur interchromosomally.

Use of avian myeloblastosis virus reverse transcriptase at high temperature for sequence analysis of highly structured RNA

Avian myeloblastosis virus reverse transcriptase (AMV RT) is routinely used in the sequence analysis of RNA and DNA templates. We review the various methods for dealing with secondary structures that would otherwise result in premature termination or sequence compression. Based on our experience in sequencing the 11-kb single-stranded RNA genome of lymphocytic choriomeningitis virus, we have found that raising the reaction temperature above 47 degrees C is the simplest way to overcome template secondary structure, and the use of 98% formamide gels is the simplest way to overcome product secondary structure.

The deletion of 41 proximal nucleotides reverts a poliovirus mutant containing a temperature-sensitive lesion in the 5' noncoding region of genomic RNA

We generated a number of small deletions and insertions in the 5' noncoding region of an infectious cDNA copy of the poliovirus RNA genome. Transfection of these mutated cDNAs into COS-1 cells produced the following phenotypic categories: (i) wild-type mutations, (ii) lethal mutations, (iii) mutations exhibiting slow growth or low-titer properties, and (iv) temperature-sensitive (ts) mutations. The deletion of nucleotides 221 to 224 produced a ts virus, 220D1. Mutant 220D1 was found to have a dramatic reduction in growth, virus-specific protein and RNA synthesis, and the shutoff of host cell protein synthesis at 37 or 39 degrees C compared with 33 degrees C. Temperature shift experiments showed that the mutant viral RNA is not an effective template for protein or RNA synthesis at 39 degrees C and suggested a decreased stability of the 220D1 RNA at 39 degrees C. Selection for a non-ts revertant of 220D1 yielded the virus R2, which was no longer ts for growth or viral protein and RNA synthesis. Sequencing the 5' noncoding region of the genomic RNA from R2 revealed the deletion of 41 proximal nucleotides for an overall deletion of nucleotides 184 to 228. These data suggest that the deleted sequences are nonessential to the poliovirus life cycle during growth in HeLa cells. According to computer-predicted RNA secondary structures of the 5' noncoding region of poliovirus RNA, the R2 revertant virus has deleted an entire predicted stem-loop structure.

Nucleotide sequence of the genomic region encoding alcohol dehydrogenase in Drosophila affinidisjuncta

The DNA sequence of a 3886-bp genomic region containing the alcohol dehydrogenase (Adh) gene from Drosophila affinidisjuncta, and the RNA sequences of the D. affinidisjuncta Adh transcripts, are presented. These data support the conclusion that two Adh promoters generate distinct, developmentally regulated Adh transcripts. Correlations between these sequences and the transcription map are discussed. Comparisons between these and equivalent data from D. melanogaster are also presented. We note the following observations: (1) Except at the extreme 3' end, the two genes are identically organized. (2) Drosophila Adh protein accumulates amino acid replacements at the rate of approximately 0.5 per million years. (3) Among the non-protein-coding DNA sequences, putative homologies occur in the two promoter regions.

Three spontaneous H-2Db mutants are generated by genetic micro-recombination (gene conversion) events. Impact on the H-2-restricted immune responsiveness

Sequence analysis of the mutant Dbm13, Dbm14, and Dbm24 genes indicate that they differ from the parental Db gene by 4, 1, and 8 nucleotides, respectively. The mutant sequences substituted into Dbm13 and Dbm24 are identical to those found in the Kb gene, at the homologous positions. Thus, similar to the Kb gene, the Db gene is able to undergo micro-recombination (gene conversion) events with other class I genes. Such data suggest that micro-recombination events could be an important mechanism for the diversification of all H-2 genes. The Db mutant products share a common theme: the alterations in all occur at amino acid residues whose side chains in the homologous class I HLA-A2 molecule project into the postulated peptide antigen-binding cleft, and hence, would be expected to alter the binding of foreign or self peptides. Due to such changes, the bm14 mouse has become a nonresponder in the CTL response to Moloney murine leukemia virus (M-MuLV), as the alteration of one amino acid residue at position 70 (a Gln to His) is sufficient to entirely abrogate the cell-mediated response to the virus. On the other hand, the bm13 mouse has shifted the major part of its M-MuLV restriction to Kb, a profound alteration in CTL responsiveness due to the alteration of three amino acids (Leu to Gln at 114, Phe to Tyr at 116, and Glu to Asp at 119) in a peptide stretch of beta-pleated sheet structure lining the bottom of the antigen-binding cleft. Thus, study of these mutants reveals that, in one step, micro-recombination at the genetic level has resulted at the protein level in profound changes in the immune response to viral infection. Such a mechanism operating at the population level can be a driving force during evolution for modulating the character of CTL immunity.

Molecular cloning and characterization of two rat renal kallikrein genes

Kallikreins compose a multigene family coding for a subgroup of serine proteases, which are involved in the processing of bioactive peptides. Two rat kallikrein-related genes, RSKG-7 (rat submandibular gland kallikrein gene 7) and RSKG-3, have been cloned and their sequences analyzed. RSKG-7 is approximately 4200 bases in length and consists of five exons and four introns. The 5' end region contains the variant CATAT box and TTTAAA box; the 3' end region contains the polyadenylation signal AATAAA. This gene encodes a putative 28,935-dalton preproenzyme of 261 amino acids (aa). The active enzyme consists of 237 aa and is preceded by a deduced signal peptide of 18 aa and a profragment of 6 aa. RSKG-3 is highly homologous to RSKG-7 in terms of its sequence and structure; it encodes a 28,730-dalton prepropeptide consisting of a signal peptide of 18 aa, a profragment of 6 aa, and an active peptide of 235 aa. Sequence comparisons of RSKG-7, RSKG-3, and other kallikrein-related enzymes reveal the key amino acid residues needed for both serine protease activity (His/Asp/Ser) and kallikrein-like cleavage specificity at basic amino acids. Northern blot analyses using specific oligonucleotide probes demonstrate that, among the 12 tissues studied, RSKG-7 and RSKG-3 are expressed in the rat kidney and submandibular gland. Castration of male rats results in a decrease in submandibular gland RSKG-7 mRNA, which can be restored to the normal level by treatment with thyroxine or testosterone. On the other hand, neither castration nor hormonal manipulation affects RSKG-7 mRNA levels in the kidney.

A new means of inducibly inactivating a cellular protein

This paper presents a general means of eliminating the function of a single protein without relying on genetic alterations in its structure or level of synthesis. The strategy is based on the inducible cellular expression of neutralizing antibody to inactivate the protein selectively. The feasibility of this approach is illustrated by using alcohol dehydrogenase I (ADH I) in Saccharomyces cerevisiae as a model. Heavy- and light-chain cDNAs were isolated from a hybridoma secreting an antibody which neutralizes yeast ADH I. The cDNAs were characterized with respect to their length and identity, their signal sequences were removed, and synthetic translation initiation codons were joined to them. These truncated sequences were then inserted into an inducible expression vector and shown to be expressed as stable heavy and light chains, which assemble and bind antigen. The sequences were introduced into yeast mutants containing different levels of ADH activity, and evidence is provided that the antibodies produce limited neutralization of enzyme activity in vivo. In principle, the approach can be used for any cell type in which functional antibody can be inducibly expressed.

Expression in non-lymphoid cells of mouse recombinant immunoglobulin directed against the tumour marker human placental alkaline phosphatase

From a mouse hybridoma cell line secreting a monoclonal antibody directed against the tumour marker human placental alkaline phosphatase, mRNA coding for the H and L chains of this antibody was isolated and cloned as cDNA. Sequence analysis of the H and L chain cDNAs confirmed the IgG2b,kappa subtype previously established. Recloning the H and L chain cDNA information into SV40-based vectors enabled us to obtain expression of functional immunoglobulin upon cotransfection into COS or CHO dhfr- cells. This illustrates that non-lymphoid cells also have the capacity to assemble active immunoglobulins.

A new means of inducibly inactivating a cellular protein

This paper presents a general means of eliminating the function of a single protein without relying on genetic alterations in its structure or level of synthesis. The strategy is based on the inducible cellular expression of neutralizing antibody to inactivate the protein selectively. The feasibility of this approach is illustrated by using alcohol dehydrogenase I (ADH I) in Saccharomyces cerevisiae as a model. Heavy- and light-chain cDNAs were isolated from a hybridoma secreting an antibody which neutralizes yeast ADH I. The cDNAs were characterized with respect to their length and identity, their signal sequences were removed, and synthetic translation initiation codons were joined to them. These truncated sequences were then inserted into an inducible expression vector and shown to be expressed as stable heavy and light chains, which assemble and bind antigen. The sequences were introduced into yeast mutants containing different levels of ADH activity, and evidence is provided that the antibodies produce limited neutralization of enzyme activity in vivo. In principle, the approach can be used for any cell type in which functional antibody can be inducibly expressed.

Sequence and transcriptional analysis of a chloroplast insert in the mitochondrial genome of Zea mays

The complete sequence of a mitochondrial DNA insertional event containing the 3' portion of the chloroplast 23S-4.5S rRNA gene, the entire 5S rRNA gene and intervening sequence and all but the 3' 6 nucleotides of the arginine tRNA gene is reported. Also reported are both chloroplast/mitochondrial DNA junction sequences, 551 nucleotides of flanking mitochondrial sequences and the genomic location of this insert in Zea mays mitochondria. Utilizing the distinctive transcriptional pattern seen for mitochondrial RNA derived from root tissue relative to shoot tissue, we also reported a general experimental test for whether chloroplast sequences transposed to the mitochondrion are transcribed. Although results for the insert reported suggest it is transcriptionally inactive, the technique should be generally applicable to any transposed sequence.

Nucleotide sequence of the fusion and phosphoprotein genes of human respiratory syncytial (RS) virus Long strain: evidence of subtype genetic heterogeneity

The nucleotide and deduced amino acid sequences of the fusion (F) and phosphoprotein (P) genes of the Long strain of human respiratory syncytial (RS) virus have been determined from cDNA copies cloned into pBSV9 shuttle vector. Comparison of these sequences with their counterparts of other strains reveals genetic heterogeneity within the same subtype. The percentage of nucleotide and amino acid changes occurring in both proteins is similar. Thus, the Long F and P proteins share 97.9% and 98.3% amino acid identity, respectively, with their homologs of the A2 strain. Nevertheless the F2 subunit of the fusion protein accumulates 3.1 times more amino acid changes than the F1 subunit. In addition, the percentage of nucleotide changes in the 3' extracistronic sequences is 6 times higher in the P than in the F gene. These results are discussed in terms of selective pressures operating in the evolution of RS virus in nature.

Messenger RNAs of a strongly-expressed late gene of cowpox virus contain 5'-terminal poly(A) sequences

We have identified and characterized one of the most strongly-expressed genes of cowpox virus (CPV). This is the gene encoding the major protein component of the A-type inclusion bodies produced by this virus. This gene (designated the 160K gene) is transcribed late during the infection. Analyses of its mRNAs showed that these late RNAs, unlike all other characterized late mRNAs of poxviruses, are uniform in length. However, the most remarkable feature of the mRNAs of the 160K gene is the structure of their 5'-termini. Most of these mRNAs have 5'-terminal poly(A) sequences containing 5-21 residues. Furthermore, these 5'-terminal poly(A) sequences are not complementary to the corresponding region of the template strand of the viral DNA. Instead, the nucleotide sequences of the mRNA and the viral DNA diverge at the site of the three As in the sequence 5'-TAAATG-3' containing the gene's initiation codon. Consequently, the poly(A) provides the leader sequences of these mRNAs. These unusual 5'-terminal structures suggest that the late mRNAs of pox-virus genes are generated by a novel process.