Intrinsic negative feedback governs activation surge in two-component regulatory systems

PhoP and PhoQ comprise a two-component system in the bacterium Salmonella enterica. PhoQ is the sensor kinase/phosphatase that modifies the phosphorylation state of the regulator PhoP in response to stimuli. The amount of phosphorylated PhoP surges after activation, then declines to reach a steady-state level. We now recapitulate this surge in vitro by incubating PhoP and PhoQ with ATP and ADP. Mathematical modeling identified PhoQ's affinity for ADP as the key parameter dictating phosphorylated PhoP levels, as ADP promotes PhoQ's phosphatase activity toward phosphorylated PhoP. The lid covering the nucleotide-binding pocket of PhoQ governs the kinase to phosphatase switch because a lid mutation that decreased ADP binding compromised PhoQ's phosphatase activity in vitro and resulted in sustained expression of PhoP-dependent mRNAs in vivo. This feedback mechanism may curtail futile ATP consumption because ADP not only stimulates PhoQ's phosphatase activity but also inhibits ATP binding necessary for the kinase reaction.

Nyamanini and midway viruses define a novel taxon of RNA viruses in the order Mononegavirales

Here, we report the sequencing and classification of Nyamanini virus (NYMV) and Midway virus (MIDWV), two antigenically related viruses that were first isolated in 1957 and 1966, respectively. Although these viruses have been cultured multiple times from cattle egrets, seabirds, and their ticks, efforts to classify them taxonomically using conventional serological and electron microscopic approaches have failed completely. We used a random shotgun sequencing strategy to define the genomes of NYMV and MIDWV. Contigs of 11,631 and 11,752 nucleotides, representing the complete genome of NYMV and the near-complete genome of MIDWV, respectively, were assembled. Each virus genome was predicted to carry six open reading frames (ORFs). BLAST analysis indicated that only two of the ORF proteins of each virus, the putative nucleocapsid and polymerase, had detectable sequence similarity to known viral proteins. Phylogenetic analysis of these ORF proteins demonstrated that the closest relatives of NYNV and MIDWV are negative-stranded-RNA viruses in the order Mononegavirales. On the basis of their very limited sequence similarity to known viruses, we propose that NYMV and MIDWV define a novel genus, Nyavirus, in this order.

Sequence requirements for Sindbis virus subgenomic mRNA promoter function in cultured cells

The Sindbis virus minimal subgenomic mRNA promoter (spanning positions -19 to +5 relative to the subgenomic mRNA start site) is approximately three- to sixfold less active than the fully active -98 to +14 promoter region. We identified two elements flanking the -19 to +5 region which increase its transcription to levels comparable to the -98 to +14 region. These elements span positions -40 to -20 and +6 to +14 and act synergistically to enhance transcription. Nine different virus libraries were constructed containing blocks of five randomized nucleotides at various positions in the -40 to +14 region. On passaging these libraries in mosquito cells, a small subset of the viruses came to dominate the population. Sequence analysis at the population level and for individual clones revealed that in general, wild-type bases were preferred for positions -15 to +5 of the minimal promoter. Base mutagenesis experiments indicated that the selection of wild-type bases in this region was primarily due to requirements for subgenomic mRNA transcription. Outside of the minimal promoter, the -35 to -29 region contained four positions which also preferred wildtype bases. However, the remaining positions generally preferred non-wild-type bases. On passaging of the virus libraries on hamster cells, the -15 to +5 region again preferred the wild-type base but most of the remaining positions exhibited almost no base preference. The promoter thus consists of an essential central region from -15 to +5 and discrete flanking sites that render it fully active, depending on the host environment.

A novel viral RNA species in Sindbis virus-infected cells

Sindbis virus (SIN), the type alphavirus, has been studied extensively to identify the viral cis-acting sequences and proteins involved in RNA transcription and replication. However, very little is known about how these processes are coordinated. For example, synthesis of the genomic RNA and the subgenomic mRNA depends on the minus strand. Do these activities occur independently on different templates, or can replication and transcription take place simultaneously on the same template? We describe the appearance of a SIN-specific, plus-sense RNA that is intermediate in size between the genomic and subgenomic RNA species. This RNA, designated RNA II, is observed in a number of different cell lines, both early and late in infection. The number of RNA II species, their sizes, and their abundances are influenced by the subgenomic promoter. We have mapped the 3' end of RNA II to a site within the subgenomic promoter, four nucleotides before the initiation site of the subgenomic mRNA. Our results indicate that the appearance of RNA II is correlated with subgenomic mRNA transcription, such that strong or active promoters tend to increase the abundance of RNA II, relative to weak or less active promoters. RNA II is most abundantly detected with the full promoter and is at much lower abundance with the minimal promoter. The possible origins of RNA II are discussed.

Alphavirus-based expression vectors: strategies and applications

Alphaviruses are positive-strand RNA viruses that can mediate efficient cytoplasmic gene expression in insect and vertebrate cells. Through recombinant DNA technology, the alphavirus RNA replication machinery has been engineered for high-level expression of heterologous RNAs and proteins. Amplification of replication-competent alpha-virus RNAs (replicons) can be initiated by RNA or DNA transfection and a variety of packaging systems have been developed for producing high titers of infectious viral particles. Although normally cytocidal for vertebrate cells, variants with adaptive mutations allowing noncytopathic replication have been isolated from persistently infected cultures or selected using a dominant selectable marker. Such mutations have been mapped and used to create new alphavirus vectors for noncytopathic gene expression in mammalian cells. These vectors allow long-term expression at moderate levels and complement previous vectors designed for short-term high-level expression. Besides their use for a growing number of basic research applications, recombinant alphavirus RNA replicons may also facilitate genetic vaccination and transient gene therapy.

Sindbis virus vectors for expression in animal cells

Sindbis virus and other alphavirus gene expression vectors have recently been used to express and study the functions of proteins and RNA, to evaluate classical vaccine and novel antiviral approaches, and for nucleic acid immunization. The vectors will likely attract continuing, innovative applications that exploit their useful features: rapid and efficient gene expression, wide host range, and RNA genomes.

Evolution of the Sindbis virus subgenomic mRNA promoter in cultured cells

Transcription of the subgenomic mRNA of alphaviruses initiates at an internal site, called the promoter, which is highly conserved. To determine the functional significance of this conservation, we used an approach that randomizes positions -13 to -9 of the promoter to generate a library containing all possible sequences within this region, including the wild-type sequence. Viruses in the mixed population with more-efficient promoters were selected for during passaging in mammalian (BHK-21) cells. Results from early passage populations indicate that a large number of different promoters are functionally active. Analysis of eight individual viruses found that although each contained a promoter with different degrees of sequence identity to the wild-type sequence, all eight viruses produced progeny. This suggests that the mechanism for transcription allows for a diversity of sequences to serve as promoters. Further passaging of the viral library led to a population consensus sequence that increasingly resembled the wild-type sequence, despite the fact that these promoters are not constrained by the need to encode the carboxyl terminus of the nsP4 protein. Thus, conservation of the region of the promoter from -13 to -9 is in large part due to selection for promoter function, and the wild-type sequence and sequences closely similar to it seem to be optimal for promoter function in BHK-21 cells.

Host-dependent evolution of the Sindbis virus promoter for subgenomic mRNA synthesis

Alphaviruses are alternately transmitted between arthropod and vertebrate hosts. In each host, the virus transcribes a subgenomic mRNA that encodes the viral structural proteins which encapsidate the genome to form progeny virions. Transcription initiates at an internal site called the promoter. To determine if promoter utilization varies in mammalian versus mosquito cells, we used these cells as hosts to select for active promoters among a library of different mutant promoters. Compared with that in BHK-21 cells, selection was more rapid in mosquito (C7-10) cells, with much less diversity of promoters remaining after fewer passages. Thus, promoter selection is host dependent. With further passaging, both BHK-21 and C7-10 cells selected for similar sequences that closely resemble the wild-type promoter sequence. The difference in the rates of selection is not because BHK-21-derived promoters cannot function in mosquito cells. Instead, part of the host dependence is probably due to posttranscriptional differences between BHK-21 and C7-10 cells that may require more active promoters in mosquito cells. Part of the host dependence may also be attributed to the decreased rate of transcription versus that of replication in mosquito cells. This change in regulation of subgenomic to genomic RNA synthesis appears to correlate with the extent of cleavage or pausing of the genomic RNA synthesis at or close to the promoter.

Utilization of heterologous alphavirus junction sequences as promoters by Sindbis virus

We used Sindbis virus, an alphavirus, as a model to study the evolution of the recognition of viral cis-acting sequences. During the life cycle of alphaviruses, a full-length minus-strand RNA is made and serves as a template for both genomic RNA replication and subgenomic mRNA transcription. Transcription initiates at an internal promoter site, the junction sequence, to produce a subgenomic mRNA. The junction sequences of alphaviruses are highly conserved, but they do contain a number of base differences. These could have been essentially neutral mutations during evolution, such that any of the contemporary sequences can be recognized efficiently by any of the alphaviruses. Alternately, the changes could have resulted in significant functional divergence, such that the contemporary viruses can no longer recognize heterologous junction sequences as promoters. To distinguish between these possibilities, we constructed Sindbis virus derivatives with two subgenomic mRNA promoters. One is the wild-type Sindbis virus promoter used for expression of the structural proteins. The other is either the minimal Sindbis virus promoter or the corresponding junction sequences from other alphaviruses, which are placed upstream of the bacterial chloramphenicol acetyltransferase (CAT) gene. RNA analyses were used to determine the relative promoter strengths of the various junction sequences. The results showed that all but two were recognized as promoters by Sindbis virus. CAT enzyme assays were used to measure the accumulation of CAT protein made from mRNAs transcribed by using the heterologous junction sequences as promoters. Most of the viruses expressed amounts of CAT enzyme within 10-fold of each other. The two viruses with junction sequences that were not recognized as promoters did not give significant CAT expression. We conclude that, with respect to Sindbis virus, the junction sequences are functionally conserved; i.e., most of the contemporary nucleotide differences in the junction sequences are neutral or near-neutral mutations. The functional conservation suggests that neither the cis-acting sequence nor the cognate binding site of the transcription factor can change independently. This type of coupled evolution between cis-acting sequences and their cognate viral protein binding sites may be a general phenomenon. For example, it explains the ubiquitous presence of conserved cis-acting sequences in each of the families of RNA viruses. There are implications of this hypothesis for the design of antiviral drugs.

Analysis of Sindbis virus promoter recognition in vivo, using novel vectors with two subgenomic mRNA promoters

Four types of Sindbis virus vectors, each carrying two promoters for subgenomic mRNA synthesis, were designed to measure relative promoter strengths and to survey potential contextual effects on promoter strengths. One of the promoters in each vector was used as the reference promoter, while the other was the one being tested. We used these vectors to measure the relative strengths of four promoters: the minimal promoter, an extended sequence believed to have full promoter activity, and two mutant promoters, one with an inactivating 3-nucleotide insertion called CR4.1 and the other with a 4-nucleotide deletion called delta 4. The strengths of the promoters were measured by quantitating the RNA transcribed from each promoter in vivo and also by assaying for chloramphenicol acetyltransferase activity encoded by one of the two transcripts. We found that the relative strengths of the promoters were similar in different contexts. The complete promoter was 6-fold more active, the delta 4 promoter was (surprisingly) about twice as active, and the CR4.1 promoter was 100-fold less active than the minimal promoter. At least two contextual effects were identified that can alter the activity of one or both promoters in the vectors. One effect is that given identical promoters, the 3'-proximal promoter on the minus-strand template can be more active than the 5'-proximal promoter. This may be due to preferential association of one or more components of the transcription complex for the 3' end of the minus-strand template. A second effect is promoter competition, particularly when the promoters are closely spaced.

Promoter for Sindbis virus RNA-dependent subgenomic RNA transcription

Sindbis virus is a positive-strand RNA enveloped virus, a member of the Alphavirus genus of the Togaviridae family. Two species of mRNA are synthesized in cells infected with Sindbis virus; one, the 49S RNA, is the genomic RNA; the other, the 26S RNA, is a subgenomic RNA that is identical in sequence to the 3' one-third of the genomic RNA. Ou et al. (J.-H. Ou, C. M. Rice, L. Dalgarno, E. G. Strauss, and J. H. Strauss, Proc. Natl. Acad. Sci. USA 79:5235-5239, 1982) identified a highly conserved region 19 nucleotides upstream and 2 nucleotides downstream from the start of the 26S RNA and proposed that in the negative-strand template, these nucleotides compose the promoter for directing the synthesis of the subgenomic RNA. Defective interfering (DI) RNAs of Sindbis virus were used to test this proposal. A 227-nucleotide sequence encompassing 98 nucleotides upstream and 117 nucleotides downstream from the start site of the Sindbis virus subgenomic RNA was inserted into a DI genome. The DI RNA containing the insert was replicated and packaged in the presence of helper virus, and cells infected with these DI particles produced a subgenomic RNA of the size and sequence expected if the promoter was functional. The initiating nucleotide was identical to that used for Sindbis virus subgenomic mRNA synthesis. Deletion analysis showed that the minimal region required to detect transcription of a subgenomic RNA from the negative-strand template of a DI RNA was 18 or 19 nucleotides upstream and 5 nucleotides downstream from the start of the subgenomic RNA.

A cis-acting mutation in the Sindbis virus junction region which affects subgenomic RNA synthesis

The synthesis of Sindbis virus minus-strand and genomic and subgenomic RNAs is believed to require specific cis-acting sequences or structures in the template RNAs and a combination of virus-specific proteins and host components which act in trans. A conserved sequence of about 21 nucleotides in the junction region and encompassing the start site for the subgenomic RNA has been proposed to function as the promoter on the minus-strand template for synthesis of the subgenomic RNA (J.-H. Ou, C. M. Rice, L. Dalgarno, E. G. Strauss, and J. H. Strauss, Proc. Natl. Acad. Sci. USA 79:5235-5239, 1982). We introduced a three-base insertion in this sequence, which also inserts a single amino acid near the COOH terminus of nsP4, in a cDNA clone of Sindbis virus from which infectious RNA transcripts can be generated. The phenotype of this mutant, called Toto1100CR4.1, was studied after RNA transfection of chicken embryo fibroblasts or BHK cells. The mutation leads to a drastic reduction in the level of the subgenomic RNA but does not alter the start site of the RNA. Probably as a consequence of depressed structural-protein synthesis, very few progeny virions are released and the mutant makes tiny or indistinct plaques even after prolonged incubation. The cis-acting effect of this mutation was demonstrated by incorporating either a wild-type or mutant junction region into a defective-interfering RNA and examining the relative synthesis of defective-interfering RNA-derived subgenomic RNA in vivo in the presence of wild-type helper virus. These results show that the junction region is recognized by yet unidentified viral trans-acting components for subgenomic RNA synthesis. When the Toto1100CR4.1 mutant was passaged in culture, plaque morphology variants readily arose. A total of 24 independent revertants were isolated, and 16 were characterized in detail. All revertants analyzed showed an increase in the level of subgenomic RNA synthesis. Sequence analysis of the junction region showed that all were pseudorevertants, with only two containing potentially compensating changes in the junction region. An assay was developed to identify revertants with second-site changes in trans-acting viral components involved in subgenomic RNA synthesis. At least two such revertants were identified. Mapping of these and other second-site compensating mutations may provide genetic clues as to which virus-specific protein(s) is responsible for interaction with the conserved junction region to promote subgenomic RNA synthesis.

Tn5supF, a 264-base-pair transposon derived from Tn5 for insertion mutagenesis and sequencing DNAs cloned in phage lambda

We constructed a derivative of transposon Tn5 called Tn5supF for insertion mutagenesis and sequencing DNAs cloned in phage lambda. This element carries a supF amber-suppressor tRNA gene. Its insertion into lambda can be selected by plaque formation by using nonsuppressing (sup0) Escherichia coli for amber mutant lambda phage and sup0 dnaB-amber E. coli for nonamber lambda phage. Tn5supF is just 264 base pairs long. It transposes efficiently and inserts quasi-randomly into DNA targets. The unique sequences near its termini can be used as primer binding sites for dideoxynucleotide DNA sequencing, thus permitting the direct sequencing of DNAs cloned in phage lambda without subcloning.

Effect of base pair mismatches on recombination via the RecBCD pathway

The effect of base pair mismatches on recombination via the RecBCD pathway was studied in mutS and wild-type Escherichia coli, using substrates that contain single or multiple mismatches. Recombination between homologous DNA inserts in lambda phage and pBR322-derived plasmids forms phage-plasmid cointegrates that result from an odd numbers of crossovers. In the mutS host, when the sequence homology of a pair of 405 bp substrates decreased from 100% to 89%, the recombinant frequency decreased by about 9-fold, while in the wild-type host the decrease was about 240-fold. These results suggest that multiple mismatches can reduce recombinant frequencies by impeding the mechanism of recombination itself, and by provoking mismatch repair. Single mismatches in 31 bp substrates caused reductions in recombinant frequencies of 2- or 12-fold, depending on the location of the mismatch. However, unlike the reduction by multiple mismatches, the reduction of the recombinant frequencies by single mismatches was the same in both mutS and wild-type hosts. Thus a single mismatch is sufficient to impede recombination, and mismatch repair seems unable to act on single mismatches in very short homologies during recombination.

Association of the Sindbis virus RNA methyltransferase activity with the nonstructural protein nsP1

SVLM21 is a mutant of Sindbis virus, which in contrast to SVSTD, is able to replicate in Aedes albopictus mosquito cells deprived of methionine. We have obtained evidence that the basis of this low methionine-resistance (LMR) phenotype is the generation of an altered RNA methyltransferase with an increased affinity for S-adenosylmethionine (ado met). We now report that following the substitution of the nucleotide sequence, 126-504, from SVLM21 cDNA for the corresponding sequence of the Toto 1101 plasmid (infectious Sindbis viral RNA can be transcribed from this plasmid) we were able to generate recombinant Sindbis virus (SVMS-65a) with the LMR phenotype. (SVTOTO virus derived from Toto 1101, like SVSTD, lacks the LMR phenotype.) As was the case with SVLM21, SVMS-65a not only possessed the LMR phenotype but also showed an increased sensitivity to Neplanocin A, a potent inhibitor of S-adenosylhomocysteine (ado hcy) hydrolase. Sequencing of the nucleotide 126-504 region from SVLM21 revealed two mutations; these mutations occurred in adjacent codons and lead to two predicted amino acid changes in the SV nsPl protein; at residue 87, from Arg to Leu, and at residue 88 from Ser to Cys. Since the nucleotide sequence 126-504 lies entirely within the gene for nsP1, we conclude that the RNA methyltransferase activity generated by SV is associated with nsP1. We suggest that residues 87 and 88 in nsP1, where the amino acid changes in SVLM21 nsP1 have occurred, are at or near the binding site for ado met; we also suggest that these changes in nsP1 are responsible for the increased affinity of the SVLM21 RNA methyltransferase for ado met and thereby for the LMR phenotype. Alternatively, it is possible that the binding site for ado met is elsewhere on nsP1 or even on another protein, and that the changes at residues 87 and 88 lead to an alteration of the binding site.

Sindbis virus: an efficient, broad host range vector for gene expression in animal cells

Sindbis virus, an enveloped virus with a single-stranded RNA genome, was engineered to express a bacterial protein, chloramphenicol acetyltransferase (CAT), in cultured insect, avian, and mammalian cells. The vectors were self-replicating and gene expression was efficient and rapid; up to 10(8) CAT polypeptides were produced per infected cell in 16 to 20 hours. CAT expression could be made temperature-sensitive by means of a derivative that incorporated a temperature-sensitive mutation in viral RNA synthesis. Vector genomic RNAs were packaged into infectious particles when Sindbis helper virus was used to supply virion structural proteins. The vector RNAs were stable to at least seven cycles of infection. The expression of CAT increased about 10(3)-fold, despite a 10(15)-fold dilution during the passaging. Sindbis virus vectors should prove useful for expressing large quantities of gene products in a variety of animal cells.

Molecular analysis of Sindbis virus pathogenesis in neonatal mice by using virus recombinants constructed in vitro

Genetic loci affecting Sindbis virus pathogenesis in neonatal mice have been examined by using a full-length cDNA clone of the virus (Toto1101). The full-length cDNA is linked to a bacteriophage SP6 promoter to facilitate the synthesis of infectious RNA transcripts in vitro. Virus derived from Toto1101 showed reduced virulence (attenuation) in neonatal mice. Replacement of the E1 glycoprotein and 6K genes of Toto1101 with cloned E1 and 6K genes derived from a virulent Sindbis virus strain, AR339 (SB), resulted in a new construct, TR2000, that gave rise to virulent virus. Sequence determinations for the entire substituted regions of TR2000, Toto1101, and related virulent and attenuated strains identified three coding differences in E1 between Toto1101 and TR2000. These differences, individually or in combination, may be responsible for the attenuated phenotype. Previous studies in this laboratory identified another attenuating mutation at amino acid position 114 of the E2 glycoprotein (N.L. Davis, F.J. Fuller, W.G. Dougherty, R.A. Olmsted, and R.E. Johnston, Proc. Natl. Acad. Sci. USA 83:6771-6775, 1986). Substitution of Arg-114 in the mutant SB-RL for Ser-114 of SB appears to confer three distinguishing phenotypes: attenuation in neonatal mice, increased sensitivity to specific E2 monoclonal antibodies, and accelerated penetration of BHK cells. Replacement of TR2000 sequences containing the codon for amino acid 114 of E2 with corresponding fragments from cDNA clones of SB or SB-RL produced two strains of Sindbis virus (TR2100 and TR2200) which were isogenic except for the E2 114 codon (Ser and Arg, respectively). The three diagnostic phenotypes cosegregated according to the origin of the codon for amino acid 114 of E2, confirming the dramatic effect of this single amino acid substitution on these three phenotypes.

Bidirectional chain-termination nucleotide sequencing: transposon Tn5seq1 as a mobile source of primer sites

The sequencing of large DNA fragments by the chain-termination method [Sanger et al., Proc. Natl. Acad. Sci. USA 74 (1977) 5463-5467] has generally required extensive manipulations to bring all parts of the fragment near a specific primer-binding site, or the repeated synthesis of new oligodeoxynucleotide primers. Here we develop a more efficient approach, the use of a transposable element to insert primer binding sites at random in the DNA of interest. We constructed a Tn5 derivative called Tn5seq1 with unique DNA segments near each end so that oligodeoxynucleotides matching them could serve as primers for sequencing in each direction from any Tn5seq1 insertion site. Our experiments demonstrate the use of Tn5seq1 for sequencing in pBR322 plasmids and also in uncloned DNAs of the Escherichia coli chromosome. The unique segments near the left and right ends of Tn5seq1 are promoters from phages T7 and SP6, respectively, to permit the efficient transcription of adjacent DNAs in vivo or in vitro.

Production of infectious RNA transcripts from Sindbis virus cDNA clones: mapping of lethal mutations, rescue of a temperature-sensitive marker, and in vitro mutagenesis to generate defined mutants

We constructed full-length cDNA clones of Sindbis virus that can be transcribed in vitro by SP6 RNA polymerase to produce infectious genome-length transcripts. Viruses produced from in vitro transcripts are identical to Sindbis virus and show strain-specific phenotypes reflecting the source of RNA used for cDNA synthesis. The cDNA clones were used to confirm the mapping of the causal mutation of ts2 to the capsid protein. A general strategy for mapping Sindbis virus mutations is described and was used to identify two lethal mutations in an original full-length construct which did not produce infectious transcripts. An XbaI linker was inserted in the cDNA clone near the transcriptional start of the subgenomic mRNA; the resulting virus retains the XbaI recognition sequence, thus providing formal evidence that viruses are derived from in vitro transcripts of cDNA clones. The potential applications of the cDNA clones are discussed.

Efficient RecABC-dependent, homologous recombination between coliphage lambda and plasmids requires a phage ninR region gene

A phage lambda gene that gives a 100-fold increase in recombinant frequencies for RecABC pathway-mediated, phage-plasmid homologous recombination (Shen and Huang 1986) maps to ninG (orf 204) of lambda. We call this gene rap, for recombination adept with plasmid. A similar determinant exists in Charon 4A and maps in phi 80-derived sequences, between nin5 and the Rz homology with lambda. The absence of the Rap+ phenotype from certain lambda vectors explains the inefficiency of screening the resulting phage libraries using phage-plasmid homologous recombination. The mapping of rap permits the construction of lambda vectors more suitable for this screening technique.

Syrinx 2A: an improved lambda phage vector designed for screening DNA libraries by recombination in vivo

The Syrinx 2A phage and pi AN13 plasmid were designed for screening of DNA libraries by homologous recombination in vivo. Syrinx 2A carries multiple cloning sites and a recently identified lambda gene, rap (recombination adept with plasmid), required for efficient phage-plasmid recombination. We describe a rapid, reliable, and technically easy method to screen Syrinx 2A libraries, expand the resulting phage-plasmid cointegrates, and subclone plasmid in as little as 2 days. Recombination screening allows one specific member of a closely related multigene family to be isolated selectively.

Structure of the T15 VH gene subfamily: identification of immunoglobulin gene promotor homologies

We have sequenced and analyzed the flanking and coding regions of four closely related mouse VH gene segments referred to as the T15 gene subfamily. We have found that although the sequence homologies between the four members of this family are greatest in the coding region, significant homologies extend into the leader sequences and the flanking regions as well. Sequence comparisons of the promoter regions of other VH gene segments indicate that the octamer promoter sequence is part of a larger conserved sequence that may play an important role in immunoglobulin gene transcription. Analysis of the lambda clones containing the members of this subfamily indicate that despite the close linkage of two of the members, the average number of kilobases of DNA between the germ-line gene segments of this family is likely to be very great.

Structure of the T15 VH gene subfamily: identification of immunoglobulin gene promotor homologies

We have sequenced and analyzed the flanking and coding regions of four closely related mouse VH gene segments referred to as the T15 gene subfamily. We have found that although the sequence homologies between the four members of this family are greatest in the coding region, significant homologies extend into the leader sequences and the flanking regions as well. Sequence comparisons of the promoter regions of other VH gene segments indicate that the octamer promoter sequence is part of a larger conserved sequence that may play an important role in immunoglobulin gene transcription. Analysis of the lambda clones containing the members of this subfamily indicate that despite the close linkage of two of the members, the average number of kilobases of DNA between the germ-line gene segments of this family is likely to be very great.

Molecular dissection of the murine antibody response to streptococcal group A carbohydrate

Monoclonal antibodies (mAb) to streptococcal group A carbohydrate (GAC) are encoded by a minimum of two VH, four JH, four V kappa, three J kappa, one V lambda, and one J lambda gene segments. The IdX, IdI-1, and Id5 idiotypic determinants are expressed by anti-GAC mAb and are found on free kappa chains. Each pattern of these determinants is encoded by a distinct V kappa gene segment, apparently without the requirement for a particular J kappa, VH, or JH gene segment, or somatic mutation. In contrast, the binding site-associated idiotypic determinant IdI-3a does not correlate with any single V or J gene segment.

Homologous recombination in Escherichia coli: dependence on substrate length and homology

We studied the in vivo recombination between homologous DNA sequences cloned in phage lambda and a pBR322-derived plasmid by assaying for the formation of phage-plasmid cointegrates by a single (or an odd number of) reciprocal exchange. (1) Recombination proceeds by the RecBC pathway in wild-type cells and by low levels of a RecF-dependent pathway in recBC- cells. The RecE pathway appears not to generate phage-plasmid cointegrates. (2) Recombination is linearly dependent on the length of the homologous sequences. In both RecBC and RecF-dependent pathways there is a minimal length, called the minimal efficient processing segment (MEPS), below which recombination becomes inefficient. The length of MEPS is between 23-27 base pairs (bp) and between 44-90 bp for the RecBC- and RecF-dependent pathways, respectively. A model, based on overlapping MEPS, of the correlation of genetic length with physical length is presented. The bases for the different MEPS length of the two pathways are discussed in relationship to the enzymes specific to each pathway. (3) The RecBC and the RecF-dependent pathways are each very sensitive to substrate homology. In wild-type E. coli, reduction of homology from 100% to 90% decreases recombinant frequency over 40-fold. The homology dependence of the RecBC and RecF-dependent pathways are similar. This suggests that a component common to both, probably recA, is responsible for the recognition of homology.

A computer simulation of evolutionary forces controlling the size of a multigene family

A Monte Carlo-type simulation of the evolution of a multigene family was performed. The model was designed to study the selective forces which may control the size of a multigene family. As expected, we find that direct selection on the size of the multigene family can control its size. More important, we find that selection acting upon the family as a single functional unit, in conjunction with homologous but unequal crossing over, can also control the size of a multigene family.

Bursectomy in ovo Blocks the Generation of Immunoglobulin Diversity

Immunoglobulins made by chickens bursectomized in ovo on day 11 of incubation were studied by two-dimensional gel electrophoresis. All such bursectomized chickens have limited diversity in their immunoglobulin molecules. A range of different degrees of diversity restriction was found in individual bursectomized chickens. The limited immunoglobulin diversity was stable for at least 20 weeks in that the same spots were found over this time span. Bursectomized chickens that responded to repeated antigen challenge had sheep erythrocyte- and dinitrophenol-specific antibodies of limited diversity. Different bursectomized responders made almost identical antigen-specific antibodies. The results were interpreted as indicating that individual bursectomized birds had been blocked at different points during the developmental generation of immunoglobulin diversity, and that the genetic mechanisms that underlie the developmental diversification of clones of B cells lead to a sequential generation of very similar antibody molecules in different embryos.

Bursectomy in ovo blocks the generation of immunoglobulin diversity

Immunoglobulins made by chickens bursectomized in ovo on day 11 of incubation were studied by two-dimensional gel electrophoresis. All such bursectomized chickens have limited diversity in their immunoglobulin molecules. A range of different degrees of diversity restriction was found in individual bursectomized chickens. The limited immunoglobulin diversity was stable for at least 20 weeks in that the same spots were found over this time span. Bursectomized chickens that responded to repeated antigen challenge had sheep erythrocyte- and dinitrophenol-specific antibodies of limited diversity. Different bursectomized responders made almost identical antigen-specific antibodies. The results were interpreted as indicating that individual bursectomized birds had been blocked at different points during the developmental generation of immunoglobulin diversity, and that the genetic mechanisms that underlie the developmental diversification of clones of B cells lead to a sequential generation of very similar antibody molecules in different embryos.

The area-code hypothesis: the immune system provides clues to understanding the genetic and molecular basis of cell recognition during development

Numberous studies of embryogenesis have provided evidence for highly specific cell-surface recognition phenomena. These include both the interactions of neighboring cells and the specific cellular migrations which occur as the developmental program of the embryo progresses. The area-code hypothesis elaborate here is an attempt to provide a framework for understanding cell-recognition phenomena in development. This hypothesis is based on extensive genetic, molecular, and cellular studies of the immune system. These studies suggest that the following events occur during the differentiation of antibody-producing cells. 1) Somatic cell lines of antibody-producing cells undergo a modification of their DNA as they become committed to synthesize a particular type of antibody molecule. This chromosomal modification event is probably a DNA translocation which leads to a somatic rearrangement of certain antibody genes. 2) In each of the specific cell lineages the new arrangement of DNA is inherited by all subsequent generations of cells. 3) The developmental programs which control these genetic alterations may be employed in a programmed and reproducible fashion. This programming of antibody development is suggested because different embryos appear to become committed to the production of identical antibody molecules in the same developmental sequence. 4) Antibody molecules are initially displayed on the cell surface where they serve as highly specifici receptors to trigger the cell to proliferate and differentiate upon interacting with appropriate external molecular signals. 5) Antibody-producing cells display combinations of different molecules on their surfaces which cause each of a very large number of different cells to interact differently with their environment. 6) The genes which code for many of these cell-surface molecules are organized into multigene families. These observations as well as information from other developmental systems have led us to propose the area-code hypothesis. This hypothesis is concerned with the structure, function, and regulation of cell-surface molecules that mediate recognition phenomena during embryogenesis. Area-code molecules are cell-surface molecules which are involved in the specific recognition phenomena during growth and development. These molecules provide cells with distinct cell-surface addresses or phenotypes, and provide the basis for the specificity in cell-cell recognition during cell migrations and cell-cell interactions, as well as serving as receptors for diffusible differentiation signals. The area-code hypothesis has 3 main postulates. i) There is a progressive display of specific combinations of area-code molecules on the surfaces of cells during development. ii) The genetic programs which determine the specific expression of area-code molecules are in part controlled by DNA modifications. These chromosomal modifications are believed to channel cells into specific lineages uith progressively restricted developmental options...

Application of latex microspheres in the isolation of plasma membranes. Affinity density perturbation of erythrocyte membranes

Immunolatex spheres, originally developed as visual markers for scanning electron microscopy, were employed as membrane density perturbation reagents. Methacrylate spheres were bound to antibody molecules and used to label antigens on erythrocytes. Ghosts prepared from labeled cells were subjected to isopycnic centrifugation on continuous sucrose and dextran gradients. It was found that the labeled erythrocyte membranes had a substantially higher density than unlabeled membranes. The extent to which the membrane density was shifted on a given gradient depended on the number, size and density of the latex spheres and could be closely predicted by theory. These results suggest that the reagents and techniques described here have potential application for the isolation of plasma membranes from more complex cell types.