Detection of activated Mr 21,000 protein, the product of ras oncogenes, using antibodies with specificity for amino acid 12

Antisera raised to a set of chemically synthesized peptides spanning position 12 of ras Mr 21,000 protein (p21) (residues 5 to 17) were able to distinguish between different forms of p21 according to the amino acid at the twelfth codon. The peptide immunogens differed in one amino acid corresponding to position 12 of the protein; the substitutions were valine, serine, arginine, aspartate, alanine, or cysteine at this position. Normal p21 contains glycine at position 12; the other amino acid substitutions are those which would result from a single base change in codon 12 and may therefore be the activating mutations most likely to occur in human tumors. The peptide antisera were evaluated by the Western immunoblot procedure for reactivity with v-ki-ras p21 expressed in Escherichia coli containing the corresponding position 12 mutations. Five of the antisera reacted with p21, and of these, anti-serine, -valine, -arginine, and -aspartate peptide antibodies were specific for their cognate protein. Similar analysis using mammalian cells as sources of position 12 variant forms of p21 demonstrated the ability of these antisera to distinguish among their oncogenic forms of p21 differing by single amino acid substitutions.

The evolutionarily conserved repetitive sequence d(TG.AC)n promotes reciprocal exchange and generates unusual recombinant tetrads during yeast meiosis

We have studied the genetic behavior of the alternating copolymer d(TG.AC)n inserted into a defined position in the genome of the yeast Saccharomyces cerevisiae. When d(TG.AC)n sequences were present at the HIS3 locus on homologous chromosomes, diploid cells undergoing meiosis generated an excess of tetrads containing reciprocally recombined products with crossover points close to the repetitive DNA insert. Most of these tetrads exhibited gene conversion of a d(TG.AC)n insert. However, the insertion of d(TG.AC)n sequences had no effect on the frequency of gene conversion of closely linked marker genes. Surprisingly, when d(TG.AC)n sequences were present on only one homolog at the HIS3 locus, one-half of the tetrads exhibiting nonparental segregation for marker genes that flanked the repetitive DNA insert were very unusual and appeared to have arisen by multiple recombination events in the vicinity of the d(TG.AC)n insert. Similar multiply recombinant tetrads were seen in crosses in which d(TG.AC)n sequences were present on both homologs. Combined, the data strongly suggest that d(TG.AC)n sequences significantly enhance reciprocal meiotic recombination and may be important in causing multiple recombination events to occur within a relatively small region of the yeast chromosome. Molecular evidence is presented that clearly documents the postmeiotic segregation of an 80-base stretch of d(TG.AC)n.

Enzymatic amplification of beta-globin genomic sequences and restriction site analysis for diagnosis of sickle cell anemia

Two new methods were used to establish a rapid and highly sensitive prenatal diagnostic test for sickle cell anemia. The first involves the primer-mediated enzymatic amplification of specific beta-globin target sequences in genomic DNA, resulting in the exponential increase (220,000 times) of target DNA copies. In the second technique, the presence of the beta A and beta S alleles is determined by restriction endonuclease digestion of an end-labeled oligonucleotide probe hybridized in solution to the amplified beta-globin sequences. The beta-globin genotype can be determined in less than 1 day on samples containing significantly less than 1 microgram of genomic DNA.

Use of pooled DNA samples to detect linkage disequilibrium of polymorphic restriction fragments and human disease: studies of the HLA class II loci

A rapid method has been developed and used to search for restriction fragment length polymorphisms (RFLPs) that are in linkage disequilibrium with disease-associated loci. By using genomic blot-hybridization analysis with DQ beta-chain and DR beta-chain cDNA probes, we examined DNA polymorphisms within the HLA class II loci associated with susceptibility to insulin-dependent mellitus (IDDM). To facilitate the search for informative RFLPs, we compared pooled DNA samples from IDDM patients with pooled DNA samples from randomly selected control individuals, instead of using the conventional approach of examining DNA samples from individuals in two groups. (The conditions under which this approach is useful are treated theoretically in the Appendix.) Several specific polymorphic restriction fragments associated with IDDM were revealed by using this economical and rapid approach. The restriction enzymes and probes identified as informative in this screening were then used to analyze HLA-DR-typed IDDM families, homozygous typing cells, and unrelated individuals to determine the association of the specific restriction fragments with HLA-DR serological type and the frequency in control and IDDM populations. Some individual polymorphic fragments for which the IDDM population was enriched correlated strongly with HLA-DR3, whereas others correlated strongly with HLA-DR4. Some fragments (e.g., a 10-kilobase Taq I fragment detected with the DR beta probe) that were more prevalent in the IDDM population subdivided the serologically defined HLA-DR type and may be informative markers for IDDM susceptibility.

Antibodies specific for amino acid 12 of the ras oncogene product inhibit GTP binding

An antibody (anti-p21ser) was raised against a ras p21-related synthetic peptide and was able to recognize specifically the substitution of serine for glycine at amino acid 12 of p21. This substitution causes oncogenic activation of p21. Anti-p21ser was found to immunoprecipitate v-Ki-ras p21 and to strongly inhibit its ability to autophosphorylate and to bind GTP in an immunoabsorption assay. Furthermore, binding of the antibody to p21 was specifically inhibited by GTP or GDP, suggesting that amino acids around position 12 are part of the GTP/GDP binding site. These results, taken together with the observation that the microinjection of anti-p21ser into cells transformed by v-Ki-ras p21 causes a transient reversion of the cells to a normal phenotype [Feramisco, J. R., Clark, R., Wong, G., Arnheim, N., Milley, R. & McCormick, F. (1985) Nature (London) 314, 639-642], support the idea that interaction of p21 with guanine nucleotides is crucial to the transforming function of this protein.

Recombination hot spot in the human beta-globin gene cluster: meiotic recombination of human DNA fragments in Saccharomyces cerevisiae

We describe a novel system for the analysis of sequence-specific meiotic recombination in Saccharomyces cerevisiae. A comparison of three adjacent restriction fragments from the human beta-globin locus revealed that one of them, previously hypothesized to contain a relative hot spot for genetic recombination, engages in reciprocal exchange during yeast meiosis significantly more frequently than either of the other two fragments. Removal of the longest of four potential Z-DNA-forming regions from this fragment does not affect the high frequency of genetic recombination.

Transient reversion of ras oncogene-induced cell transformation by antibodies specific for amino acid 12 of ras protein

The proteins encoded by the ras oncogene are thought to trigger expression of the transformed phenotype in some types of cancer cells. In human cells, the ras protein family consists of several members including normal (proto-oncogene) and mutant (oncogene) forms. In general, the proto-oncogene forms are thought to be involved in the normal growth control of cells, while the mutant forms (which apparently result from somatic mutation of the normal ras genes) appear to be responsible, in part, for the loss of normal growth control. On microinjection into living normal cells, the purified ras oncogene protein (p21) induces a characteristic loss of growth control in cells within several hours. The mutant forms of the different ras proteins typically contain a single amino-acid change, usually at position 12 or less frequently at position 61. Here we report that microinjection of antibodies specific for amino acid 12 of the oncogenic v-Ki-ras protein into cells transformed by this protein causes a transient reversion of the cells to a normal phenotype. The fact that this antibody inhibits binding of GTP to the v-Ki-ras protein supports the notion that GTP binding is essential to the transforming function of this oncogene product.

The absence of a human-specific ribosomal DNA transcription factor leads to nucleolar dominance in mouse greater than human hybrid cells

The basis for nucleolar dominance in mouse-human cell hybrids which contained all of the mouse chromosomes but an incomplete set of human chromosomes (M greater than H) was examined at the molecular level. S1 mapping data showed that these cells had the expected levels of steady-state rRNA transcribed from mouse ribosomal gene (rDNA) transcription units but undetectable levels of rRNA derived from the human rDNA transcription templates that are also present. RNA polymerase I-dependent, cell-free transcription extracts were made from three hybrid lines and were found to be capable of transcribing cloned rDNA templates of mouse but not human origin. Partially purified human factors required for rDNA transcription in vitro were added to the M greater than H extracts. One fraction with almost no RNA polymerase I activity conferred on these hybrid cell extracts the ability to transcribe a human rDNA template. These rescue experiments suggested that this required human-specific rDNA transcription factor(s) was effectively absent from the lines we examined and could account for nucleolar dominance in M greater than H hybrid cells.

Species-specific rDNA transcription is due to promoter-specific binding factors

RNA polymerase I transcription factors were purified from HeLa and mouse L cell extracts by phosphocellulose chromatography. Three fractions from each species were found to be required for transcription. One of these fractions, virtually devoid of RNA polymerase I activity, was found to form a stable preinitiation complex with small DNA fragments containing promoter sequences from the homologous but not the heterologous species. These species-specific DNA-binding factors can explain nucleolar dominance in vivo in mouse-human hybrid somatic cells and species specificity in cell-free, RNA polymerase I-dependent transcription systems. The evolution of species-specific transcriptional control signals may be the natural outcome of a special relationship that exists between the RNA polymerase I transcription machinery and the multigene family coding for rRNA.

Structure and evolution of human and African ape rDNA pseudogenes

We discuss the evolutionary significance of four aberrant 18S rDNA clones that were obtained from human, chimpanzee, and gorilla DNA libraries. We show that these clones carry representatives of a small 18S rDNA pseudogene family that arose in a common ancestor of these species. Aspects of their structure and phylogenetic distribution suggest that the 18S pseudogenes no longer interact genetically with normal ribosomal genes and therefore may not be linked to nucleolus organizer regions.

Nucleotide sequence of the genetically labile repeated elements 5' to the origin of mouse rRNA transcription

We have determined the complete nucleotide sequence of a cloned Balb/c mouse rDNA NTS fragment containing 13 tandem copies of a 135 bp subrepeating segment. This repetitious region (VrDNA) lies close to the origin of ribosomal RNA transcription. Analyses of these VrDNA subrepeats from Balb/c and a related species, Mus pahari, reveal regions of inverted repeat DNA as well as large poly T tracts, either of which may be significant to the generation of the high levels of VrDNA copy number variation found in wild and inbred mice and/or the modulation of rRNA synthesis. Unlike the highly homogeneous subrepeats in the Xenopus laevis NTS repetitious regions, the VrDNA subrepeats differ from one another on the average by about 13%. Sequence analysis and Southern hybridization studies have also shown that, unlike the Xenopus and Drosophila NTS, extensive duplications of sequences found surrounding the mouse rRNA initiation site are found neither in the VrDNA region nor 6 kb further upstream in the NTS.

Distribution of ribosomal gene length variants among mouse chromosomes

The ribosomal genes (rDNA) in mouse inbred strains have a multichromosomal distribution. Using a structural feature of rDNA [variable length rDNA segment (VrDNA)] that shows length polymorphism within and among inbred strains, we studied the chromosomal distribution of the variant ribosomal gene type through genetic analysis. Our results show that five of the length variant classes can be divided into three discrete linkage groups. The variants present on a particular chromosome pair appear to be unique to that pair and absent from nonhomologous chromosomes. The chromosomal location of particular variants appears to be the same in two unrelated inbred strains suggesting that the observed linkage patterns predate the origin of inbred mice. The nonrandom chromosomal distribution of these rDNA classes suggests that only a limited degree of genetic exchange occurs among nucleolus organizer regions on nonhomologous chromosomes. We have localized one particular VrDNA linkage group to chromosome 12. These and other restriction fragment polymorphisms can be used in the construction of detailed mouse linkage maps.

Identification of the in vivo and in vitro origin of transcription in human rDNA

A Hela cell /-100 extract primed with a purified human rDNA containing clone, has been shown to be capable of initiating specific alpha-amanitin-resistant RNA transcripts. By using a number of truncated templates, the site of RNA polymerase I initiation in vitro has been identified. The origin of transcription in vitro and in vivo was further defined by S1-mapping studies with total Hela cell RNA or RNA isolated from the in vitro transcription reaction. The initiation site was found to be the same. The nucleotide sequence of an 848 bp region around the initiation site, has also been determined. A perfect 15 bp homology has been found to exist between human and mouse rDNA very close to the origin of transcription, although little homology exists elsewhere. Sequences homologous to the origin of transcription region were not found repeated within a 12 kb non-transcribed spacer segment upstream from it.

A member of a new repeated sequence family which is conserved throughout eucaryotic evolution is found between the human delta and beta globin genes

A new class of human interspersed repeated sequences distinct from the AluI family was found by screening a human gene library with a mouse ribosomal gene non-transcribed spacer probe (rDNA NTS). A member of this sequence family was localized to a 251 bp segment between the human delta and beta globin genes: a region previously judged to be devoid of repeated DNA. The complete nucleotide sequence of this segment revealed a tandem block of 17 TG dinucleotides, a feature hypothesized by others to be a recombination hot spot responsible for gene conversion in the gamma globin locus region. When the genomes of Xenopus, pigeon, slime mold and yeast were examined, reiterated sequences homologous to both the mouse rDNA NTS and human globin repeat were found in every case. The discovery of this extraordinarily conserved repeated sequence family appears to have depended upon not using salmon sperm DNA during hybridization. The use of eucaryotic carrier DNA may bias the search for repeated sequences against any which may be highly conserved during eucaryotic evolution.

Human nucleolus organizers on nonhomologous chromosomes can share the same ribosomal gene variants

The distributions of three human ribosomal gene polymorphisms among individual chromosomes containing nucleolus organizers were analyzed by using mouse--human hybrid cells. Different nucleolus organizers can contain the same variant, suggesting the occurrence of genetic exchanges among ribosomal gene clusters on nonhomologous chromosomes. Such exchanges appear to occur less frequently in mice. This difference is discussed in terms of the nucleolar organization and chromosomal location of ribosomal gene clusters in humans and mice.

Molecular evidence for genetic exchanges among ribosomal genes on nonhomologous chromosomes in man and apes

We have found that human and ape ribosomal genes undergo concerted evolution involving genetic exchanges among nucleolus organizers on nonhomologous chromosomes. This conclusion is based upon restriction enzyme analysis of the ribosomal gene families in man and five ape species. Certain structural features were found to differ among (but not within) species even though the ribosomal genes have a multichromosomal distribution. Genetic exchanges among nucleolus organizer regions may be related to the well-known phenomenon of acrocentric chromosome associations observed in man and apes. Length variation in a region of the nontranscribed spacer was found in both chimpanzee species we examined. The nature of this length variation was found to be identical to that previously described in man. The origin of the length variation and its polymorphism within these three species might be explained by unequal alignment and unequal cross-over among the ribosomal genes. An especially surprising finding was a nucleotide sequence polymorphism present in each individual human and ape we examined. Some ribosomal genes of each individual have a HindII site in the 28S gene about 800 base pairs from the EcoRI site in this gene. The remaining 28S genes lack this HindII site. The presence of this polymorphism within individuals of every species we examined suggests that it has been maintained by natural selection.

Structure and organization of the highly repeated and interspersed 1.3 kb EcoRI-Bg1II sequence family in mice

EcoRI digestion of total mouse DNA yields a prominant 1.3 kb fragment amounting to between 1 and 2% of the mouse genome. The majority of the 1.3 kb EcoRI fragments have a single Bg1II site 800 bp from one end. This EcoRI-Bg1II sequence family shows HindIII and HaeIII sequence heterogeneity. We have cloned representatives of the EcoRI-Bg1II gene family in Charon 16A and studied their structure and organization within the genome. The cloned 1.3 kb fragments show the expected restriction enzyme patterns as well as additional heterogeneity. Representatives of the EcoRI-Bg1II sequence family were found to be interspersed throughout the mouse genome as judged by CsCl density gradient centrifugation experiments. Family members were also found to be organized in higher order repeating units. Homologous sequences were also found in other rodent species including rat and Chinese hamster. Cross hybridization between a cloned 1.3 kb mouse fragment and a cloned CHO repeated sequence is of special interest since the latter has been shown to contain sequences homologous to the Human A1uI family by nucleotide sequencing.

Mitochondrial DNA polymorphism: evidence that variants detected by restriction enzymes differ in nucleotide sequence rather than in methylation

Restriction enzyme analysis of mtDNAs for the purpose of determining sequence divergence rests on the assumption that variant recognition sites differ with respect to sequence and not methylation. This assumption was tested on two mtDNAs, A and B, which are distributed throughout the laboratory rat population and which can be distinguished by a number of restriction enzymes. The mtDNAs were cloned and the nucleotide sequences of corresponding small HindIII fragments, in which a variant EcoRI site occurs, were determined. Evidence that the fragments differ in sequence and not methylation is as follows: (i) The cloned mtDNA yielded the same fragment pattern as did native mtDNA when treated with EcoRI, Hha I, HinfI, and Hae III; (ii) three nucleotide replacements were found in the 169-base pair fragment, A.T in equilibrium G.C, A.T in equilibrium G.C, T.A in equilibrium G.C; (iii) one of these replacements, A.T in equilibrium G.C at position 80, accounts for the presence of the EcoRI site in the type A and its absence in the type B mtDNA. Examination of the sequence leads to the suggestion that these three nucleotide replacements are silent; i.e., they would not lead to amino acid substitutions in a possible encoded protein.

Mouse rDNA nontranscribed spacer sequences are found flanking immunoglobulin CH genes and elsewhere throughout the genome

When a cloned 6 kb Eco RI-Sal I fragement of mouse ribosomal gene nontranscribed spacer DNA (rDNA NTS) was used to screen a BALB/c mouse gene library, 25% of the recombinant phage hybridized with it. In situ hybridization experiments and characterization of 12 clones selected using this probe supported the idea that sequences homologous to this rDNA NTS region are scattered throughout the genome. Subsequently, sequences homologous to mouse rDNA NTS were found flanking mouse mu, alpha and gamma 2b immunoglobulin CH genes. One region was localized 3' to the mu coding sequence, an area which has been identified as an intervening sequence between the secreted C mu heavy chain terminus and the C terminal portion of the membrane-bound C mu heavy chain.

5' flanking region of immunoglobulin heavy chain constant region genes displays length heterogeneity in germlines of inbred mouse strains

Genomic Southern blotting analysis reveals that a 5' flanking DNA sequence located 1.5-2.0 kb upstream from the C mu and C alpha genes undergoes extensive length variation in the germlines of inbred and wild mice. In addition, genomic clones of the BALB/c C mu gene undergo deletion events during their propagation in Charon 4A when maintained in RecA+ bacterial strains. These deletion events occur between the JH cluster and the C mu gene and approximately 2.0 kb 5' of the C alpha gene, and may encompass several kb of DNA. Deletion events are capable of yielding a group of C mu clones which differ in size by units of 100-200 bp. The site of length variation in the mouse germline corresponds to the location of these cloning-derived deletion events, suggesting that both phenomena are reflections of intrinsic genetic properties of these Ig gene 5' flanking sequences.

Characterization of mouse ribosomal gene fragments purified by molecular cloning

Four mouse ribosomal gene fragments cloned in lambda gtWES were studied by restriction enzyme mapping and Southern transfer experiments. These fragments were found to contain 18S DNA and transcribed as well as non-transcribed spacer DNA. Variation in the structure of these mouse DNA inserts was limited to one region of spacer DNA. This variation may reflect real structural differences found in mouse ribosomal genes or possibly deletion events which occurred during cloning. The transcribed regions of the inserts appear identical to one antoher and restriction enzyme fragments from this region correspond to fragments observed in digests of total mouse DNA. These clones will be useful in studying the structure of transcribed spacer DNA including the ribosomal gene promoter.

Biochemical characterization of "LAP," a polymorphic aminopeptidase from the blue mussel, Mytilus edulis

A genetically variable naphthylamidase enzyme, previously described as "leucine aminopeptidase," was purified approximately fiftyfold, and its biochemical properties were investigated. The enzyme was renamed "aminopeptidase I." Substrate affinities demonstrate that it is an alpha-aminoacyl peptide hydrolase (E.C. 3.4.11.-). Aminopeptidase I had a monomer molecular weight of 65--68,000, average of pI of pH 4.88, and broad pH optima between 6.5 and 8.0. The enzyme was inactivated rapidly between 40 and 50 C. Antibodies from purified enzyme did not cross-react with other naphthylamidases, but aminopeptidase I activity was inhibited by immune serum. The enzyme exhibited highest naphthylamidase activity for aromatic and hydrophobic aminoacyl naphthylamides. Aminopeptidase activity was highest for aromatic and hydrophobic N-terminal residues of tripeptides. Certain divalent metal cations, p-OH-mercuribenzoate, and N-ethylmaleimide were strongly inhibitory while chelating agents activated the enzyme.