Electroporation as an effective means of introducing DNA into abalone (Haliotis rufescens) embryos.

Recombinant plasmid containing the Drosophila beta-actin promoter coupled to a beta-galactosidase cassette was linearized and introduced in fertilized eggs of the red abalone (Haliotis rufescens) by electroporation. Fertilized abalone eggs tolerated electroporation well with larval survival rates between 70% and 84% of that for non-electroporated siblings. Dot blot and Southern blot analysis were used to detect if abalone retained the foreign gene at various developmental stages. The inserted construct was retained in 70% to 100% of all abalone sampled with an average of 72% retention in the three- to seven-month-old juveniles. Maximal DNA uptake and retention was observed in abalone electroporated at 30-40 min after fertilization. Southern hybridization analysis suggested that the inserted vector was in head-to-tail concantermers integrated in the abalone genome. This preliminary study demonstrates that electroporation is an efficient means of transferring foreign DNA into abalone embryos.

Electroporation: a method for transferring genes into the gametes of zebrafish (Brachydanio rerio), channel catfish (Ictalurus punctatus), and common carp (Cyprinus carpio).

Recombinant plasmids containing the Rous sarcoma virus long-terminal repeat (RSVLTR) promoter linked to either rainbow trout (Oncorhyncus mykiss) growth hormone 1 (rtGH1) or growth hormone 2 (rtGH2) cDNA were linearized and introduced into the fertilized eggs of zebrafish (Brachydanio rerio), channel catfish (Ictalurus punctatus), and common carp (Cyprinus carpio) by both electroporation and microinjection. The latter two species had these rainbow trout constructs (RSVLTR-rtGH1cDNA or RSVLTR-rtGH2) electroporated into both gametes (i.e., sperm and unfertilized eggs) prior to fertilization, into eggs shortly after fertilization, and at the first cell division stage. Survival was determined just after hatching and again between 3 and 5 months after hatching. Polymerase chain reactions and Southern blot analyses were used to detect those individuals carrying the introduced foreign genes 3 to 5 months after hatching, respectively. Individuals analyzed by both methods yielded identical results in a double-blind study. The electroporation results were compared with groups that were microinjected. Although survival was similar, electroporation tended to produce a greater number of transgenic individuals than the microinjection procedure, and many more eggs could be treated per unit time by electroporation than microinjection. Survival was better for common carp when electroporation was performed shortly after fertilization, whereas channel catfish fared better at the first cell division stage. Electroporation prior to and shortly after fertilization, and at the first cell stage appeared to generate a large fraction of transgenic fish. We cautiously conclude that electroporation is an efficient method for introducing foreign DNA into fish gametes and embryos and may be an ideal method for treating large numbers of gametes in a modest period.

Amino acid sequences that determine the nuclear localization of yeast histone 2B.

Histone-beta-galactosidase protein fusions were used to identify the domain of yeast histone 2B, which targets this protein to the nucleus. Amino acids 28 to 33 in H2B were required for nuclear localization of such fusion proteins and thus constitute a nuclear localization sequence. The amino acid sequence in this region (Gly-29 Lys Lys Arg Ser Lys Ala) is similar to the nuclear location signal in simian virus 40 large T antigen (Pro-126 Lys Lys Lys Arg Lys Val) (D. Kalderon, B.L. Roberts, W.D. Richardson, and A.E. Smith, Cell 39:499-509, 1984). A point mutation changing lysine 31 to methionine abolished nuclear localization of an H2B-beta-galactosidase fusion protein containing amino acids 1 to 33 of H2B. However, an H2B-beta-galactosidase fusion protein containing both this point mutation and the H2A interaction domain of H2B was nuclear localized. These results suggest that H2A and H2B may be cotransported to the nucleus as a heterodimer.

Role of transcriptional and posttranscriptional regulation in expression of histone genes in Saccharomyces cerevisiae.

We analyzed the role of posttranscriptional mechanisms in the regulation of histone gene expression in Saccharomyces cerevisiae. The rapid drop in histone RNA levels associated with the inhibition of ongoing DNA replication was postulated to be due to posttranscriptional degradation of histone transcripts. However, in analyzing the sequences required for this response, we showed that the coupling of histone RNA levels to DNA replication was due mostly, if not entirely, to transcriptional regulatory mechanisms. Furthermore, deletions which removed the negative, cell cycle control sequences from the histone promoter also uncoupled histone transcription from DNA replication. We propose that the arrest of DNA synthesis prematurely activates the regulatory pathway used in the normal cell cycle to repress transcription. Although posttranscriptional regulation did not appear to play a significant role in coupling histone RNA levels to DNA replication, it did affect the levels of histone RNA in the cell cycle. Posttranscriptional regulation could apparently restore much of the periodicity of histone RNA accumulation in cells which constitutively transcribed the histone genes. Unlike transcriptional regulation, periodic posttranscriptional regulation appears to operate on a clock which is independent of events in the mitotic DNA cycle. Posttranscriptional recognition of histone RNA must require either sequences in the 3' end of the RNA or an intact three-dimensional structure since H2A- and H2B-lacZ fusion transcripts, containing only 5' histone sequences, were insensitive to posttranscriptional controls.

Identification of sequences in a yeast histone promoter involved in periodic transcription.

Sequences between a pair of divergently transcribed histone genes in Saccharomyces cerevisiae are able to confer periodic transcription during the cell cycle. This conclusion contrasts to our previous hypothesis that an ars (autonomously replicating sequence) 3' to this locus is a transcription timer for yeast histone genes. The promoter sequences required for periodic expression have been localized by deletion analysis, and isolated elements have been analyzed by insertion into a heterologous promoter. Two cell-cycle-specific promoter functions have been identified. One function activates transcription in a cell-cycle-dependent manner. The other periodically represses transcription. Negative regulation may be the predominant form of cell-cycle control, because removal of the repressing function results in constitutive expression of the histone genes.

Identification of a nuclear localization signal of a yeast ribosomal protein.

To identify a signal involved in transporting a ribosomal protein to the nucleus, we constructed hybrid genes encoding amino-terminal segments of yeast ribosomal protein L3 joined to the amino-terminal end of the entire Escherichia coli beta-galactosidase molecule. The subcellular locations of the corresponding hybrid proteins in yeast were determined by in situ immunofluorescence. The first 21 amino acids of L3 were sufficient to localize beta-galactosidase to the nucleus. This region shows limited homology to portions of other nuclear proteins identified as essential for their transport. Larger fusion proteins were also localized to the nucleus. However, a hybrid protein containing all but the 14 carboxyl-terminal amino acids from L3 initially failed to localize; this defect was corrected by inserting a glycine- and proline-containing bridge between the L3 and beta-galactosidase moieties. The renovated protein was able to associate with ribosomes, suggesting that, in addition to entering the nucleus, this hybrid polypeptide was assembled into 60S ribosomal subunits that were subsequently exported to the cytoplasm.

Targeting of E. coli beta-galactosidase to the nucleus in yeast.

In order to identify determinants governing nuclear protein localization, we constructed a set of hybrid genes by fusing the S. cerevisiae gene, MAT alpha 2, coding for a presumptive nuclear protein, and the E. coli gene, lacZ, coding for beta-galactosidase. The resultant hybrid proteins contain 3, 13, 25, 67, or all 210 amino acids of wild-type alpha 2 protein at the amino terminus and a constant, enzymatically active portion of beta-galactosidase at the carboxy terminus. Indirect immunofluorescence and subcellular fractionation studies with yeast cells containing the alpha 2-LacZ hybrid proteins indicate that the alpha 2 segment can direct localization of beta-galactosidase to the nucleus. A segment as small as 13 amino acids from alpha 2 is sufficient for this localization. Comparison of amino acid sequences of other nuclear proteins with this region of alpha 2 reveals a sequence that may be necessary for nuclear targeting. Production of some alpha 2-LacZ hybrid proteins causes cell death, perhaps as a result of improper or incomplete localization. These studies also indicate that the alpha 2 protein, argued on genetic grounds to be a negative regulator, acts in the yeast nucleus.

Identification of a sequence responsible for periodic synthesis of yeast histone 2A mRNA.

Sequences required for the regulated expression of a yeast histone 2A (H2A) gene have been investigated by using fusions between this gene and the Escherichia coli lacZ gene. Fusions containing the entire spacer region in which divergent transcription of the H2A and H2B genes is initiated result in low-level constitutive synthesis of beta-galactosidase (beta-D-galactoside galactohydrolase, EC 3.2.1.23) in yeast. Regulated expression (which is characterized by periodic synthesis during the S phase of the cell cycle) is restored when a 1.3-kilobase HindIII fragment containing a small region of the 3' end of the H2B gene is present in either orientation. The regulatory activity in this region appears to be coincident with a sequence that supports autonomous replication in yeast.

Further evidence that the rna2 mutation of Saccharomyces cerevisiae affects mRNA processing.

The relative rate at which ribosomal protein 51 (rp51) mRNA is synthesized was measured by pulse-labeling cells in vivo with [3H]adenine. Two strains of Saccharomyces cerevisiae were compared: A364A (wild type) and ts368 (rna2), a temperature-sensitive strain in which the level of rp51 mRNA decreases and an intron-containing rp51 precursor RNA increases. When cells were shifted up to the nonpermissive temperature (36 degrees C), the rate of rp51 RNA synthesis was only marginally affected (75% of wild type) by the presence of the rna2 mutation. The precursor RNA was the predominant transcription product at 36 degrees C. This precursor could be converted into RNA equal in size to mature mRNA by further incubation at either 36 or 23 degrees C in the presence of unlabeled adenine. The relative half-life of the rp51 transcripts at 36 degrees C also decreased approximately twofold in ts368 as compared with A364A. All of these data imply that the precursor (intron-containing) RNA is processed inefficiently to mature mRNA and that the rp51 precursor RNA is continuously synthesized and degraded in the mutant strain at 36 degrees C.

Periodic transcription of yeast histone genes.

Periodic transcription of yeast histone genes has been demonstrated by DNA excess filter hybridization of in vivo pulse-labeled RNA isolated from synchronous cell cultures. Using strains carrying cell division cycle (cdc) mutations, we show that both activation and termination of transcription are determined by temporally separable (cell cycle) events. Activation of histone mRNA synthesis occurs late in G1, at a point prior to initiation of DNA replication. Cessation of histone mRNA synthesis, however, is dependent upon the entry of cells into S. These results suggest a simple model for the control of histone gene transcription in which changes in chromatin that must precede the initiation of DNA replication also bring about activation of histone mRNA synthesis. Cessation of synthesis would occur once this region had been replicated and the chromatin restored to its prereplicative state.

Cell-cycle regulation of yeast histone mRNA.

The levels of H2A and H2B mRNAs as a function of cell-cycle stage were determined by hybridization methods. The analysis was extended to H3 and H4 mRNAs by in vitro translation. Cells were partitioned into cell-cycle stages either by centrifugal elutriation or by G1 synchronization with the yeast mating pheromone, alpha factor. The data lead to the following conclusions. First, histone mRNA can be detected in significant quantities only in S-phase cells. Second, the point of maximal accumulation of histone mRNA is not coincident with the point of maximal DNA synthesis; rather, histone mRNA begins accumulating very early in S, reaching a maximum when less than one half of the DNA has replicated. From this point in the cell cycle the histone mRNA levels decrease, reaching basal levels at the end of S. Third, in spite of the fact that the rate of histone mRNA accumulation is not coincident with the rate of DNA synthesis, the two processes are coupled; inhibition of DNA synthesis results in an extremely rapid disappearance of histone mRNA that is much shorter than the normal histone mRNA half-life. Fourth, there is no visible accumulation of mRNA precursors at any cell-cycle stage. We can conclude that, in yeast, histone mRNA levels are tightly and coordinately regulated throughout cell division and that this regulation most likely occurs at both transcriptional and posttranscriptional levels. We also show that the two genetically unlinked H2B genes present in yeast are both expressed at comparable levels and are regulated. The regulation is probably sequence-specific, since genes in close proximity to the histones are not subject to cell-cycle control.

Yeast histone genes show dosage compensation.

The copy number of yeast histone genes was increased by inserting an extra H2A,H2B gene pair into the haploid genome by the technique of yeast transformation. The presence of this extra gene copy has no detectable effect on cell growth. The steady-state levels of histone H2A,H2B mRNAs are not elevated in transformed strains, and they correspond to the levels measured for the parental strain. The transcription rate is increased in these strains, however, and the parental steady-state levels of histone mRNAs are maintained by increased turnover of histone transcripts. These results demonstrate that yeast histone genes display dosage compensation through the operation of posttranscriptional controls. They also suggest that maintainance of a constant ratio between histone mRNA concentration and the rate of chromosome replication may be of general importance to histone mRNA metabolism.

Histone H2B genes of yeast encode two different proteins.

The two genetically unlinked histone H2B genes isolated from Saccharomyces cerevisiae have been sequenced. The genes encode H2B proteins that are 130 amino acids in length and that differ by 4 amino acids. The changes betwen them are Ala leads to Ser, Lys leads to Ala, Thr leads to Val and Ala leads to Val at amino acid positions 2, 3, 27 and 35, respectively. A comparison of yeast H2B histones with those of higher eucaryotes demonstrates a high degree of homology clustered mainly at the carboxyl terminus. There is extensive base substitution between the two H2B genes in nucleotides that do not affect the amino acid sequence. DNA prelude sequences show 64% divergence. The coding regions differ at 49 of the 390 bases (12.6% divergence). 41 of these changes are in silent positions. By using the number of amino acid differences in the proteins we estimate that the two H2B genes are the result of an ancient duplication event.

Yeast histone mRNA is polyadenylated.

Histone mRNA from S. cerevisiae has been identified and partially purified. The RNA is quantitatively retained on oligo (dT) cellulose or poly(U) sepharose as assayed by in vitro translation or hybridization of radiolabelled cloned yeast histone sequences to RNA immobilized on DBM paper. Retention of yeast histone mRNA on either of these chromatographic systems is most likely the result of polyadenylation since, when primed with oligo (dT), the RNA is an extremely good template for reverse transcriptase, as determined by hybrid arrest translation or by hybridization to D. melanogaster histone DNA sequences.

Isolation of yeast histone genes H2A and H2B.

Analysis of cloned sequences for yeast histone genes H2A and H2B reveals that there are only two copies of this pair of genes within the haploid yeast genome. Within each copy, the genes for H2A and H2B are separated by approximately 700 bp of spacer DNA. The two copies are separated from one another in the yeast genome by a minimum distance of 35-60 kb. Sequence homology between the two copies is restricted to the genes for H2A and H2B; the spacer DNA between the genes is nonhomologous. In both copies, the genes for H2A and H2B are divergently transcribed. In addition, both plasmids code for other nonhistone proteins. Sequences coding for histones H3 and H4 have not been detected in the immediate vicinity of the genes for H2A and H2B.

Isolation of cloned DNA sequences containing ribosomal protein genes from Saccharomyces cerevisiae.

Yeast mRNA enriched for ribosomal protein mRNA was obtained by isolating poly(A)+ small mRNA from small polysomes. A comparison of cell-free translation of this small mRNA and total mRNA, and electrophoresis of the products on two-dimensional gels which resolve most yeast ribosomal proteins, demonstrated that a 5-10 fold enrichment for ribosomal protein mRNA was obtained. One hundred different recombinant DNA molecules possibly containing ribosomal protein genes were selected by differential colony hybridization of this enriched mRNA and unfractionated mRNA to a bank of yeast pMB9 hybrid plasmids. After screening twenty-five of these candidates, five different clones were found which contain yeast ribosomal protein gene sequences. The yeast mRNAs complementary to these five plasmids code for 35S-methionine-labeled polypeptides which co-migrate on two-dimensional gels with yeast ribosomal proteins. Consistent with previous studies on ribosomal protein mRNAs, the amounts of mRNA complementary to three of these cloned genes are controlled by the RNA2 locus. Although two of the five clones contain more than one yeast gene, none contain more than one identifiable ribosomal protein gene. Thus there is no evidence for "tight" linkage of yeast ribosomal protein genes. Two of the cloned ribosomal protein genes are single-copy genes, whereas two other cloned sequences contain two different copies of the same ribosomal protein gene. The fifth plasmid contains sequences which are repeated in the yeast genome, but it is not known whether any or all of the ribosomal protein gene on this clone contains repetitive DNA.

Yeast chromatin is uniformly digested by DNase-I.

The DNase I (EC 3.1.21.1) sensitivity of transcribed yeast chromatin has been examined. We find that, in contrast to chromatin from higher eukaryotes, transcribed yeast chromatin and total yeast chromatin are equally sensitive to DNase I digestion. We interpret these results to mean that the entire yeast genome exists in a state that represents a restricted proportion of total chromatin in higher eukaryotes.

Isolation and analysis of recombinant DNA molecules containing yeast DNA.

2500 recombinant plasmids containing insertions of yeast nuclear DNA have been cloned in Escherichia coli. It can be calculated that about 85% of the yeast genome is represented in this collection. The clones have been characterized by hybridization to purified RNA species. Of the 2000 clones examined, 75 contain insertions of yeast ribosomal DNA, 201 contain insertions of yeast tRNA genes, and 26 contain DNA sequences that are complementary to abundant mRNA species.

Characterization of two types of yeast ribosomal DNA genes.

The intragenic organization of ribosomal DNA from a diploid strain of Saccharomyces cerevisiae was analyzed by using recombinant DNA molecules constructed in vitro. Restriction analysis of the yeast ribosomal DNA with the EcoRI restriction enzyme indicated that eight restriction fragments were present in the ribosomal DNA of this strain: X' (1.87 X 10(6) daltons), A (1.77 X 10(6) daltons), B (1.48 X 10(6) daltons), C (1.22 X 10(6) daltons), D (0.39 X 10(6) daltons), E (0.36 X 10(6) daltons), F (0.22 X 10(6) daltons), and G (0.17 X 10(6) daltons). These fragments were distributed between two different types of ribosomal DNA genes, which had the restriction maps: (formula: see text) in which the underlined region shows the repeating unit. The diploid yeast strain contained approximately equal amounts of each of these two types of genes. The analysis of the recombinant DNA molecules also indicated that the yeast ribosomal genes are homogeneous and extensively clustered.