Selection and analysis of cloned developmentally-regulated Dictyostelium discoideum genes by hybridization-competition

In vivo transcriptional products of the chloroplast DNA of Euglena gracilis

Cloned chloroplast restriction endonuclease DNA fragments were used as hybridization probes to identify the in vivo transcriptional products of the chloroplast genome from the alga Euglena gracilis. Total cellular RNA was size fractionated by electrophoresis in denaturing gels and transferred to nitrocellulose paper. Individual plasmids containing specific chloroplast DNA fragments were radioactively labeled in vitro and hybridized to the immobilized RNA. The stable RNAs in the chloroplast were identified on the basis of their size and their origin on the chloroplast genome. Several transcripts were shown to be developmentally expressed. Some transcripts showed a possible precursor-product relationship. The rDNA was shown to be transcribed as a large transcript and then processed to the, mature rRNAs.

mRNA stabilization controls the expression of a class of developmentally regulated genes in Dictyostelium discoideum

During the development of Dictyostelium discoideum, several thousand new mRNA species appear in the cytoplasm after the cells have formed stable aggregates. Here we show that six of these late mRNAs, corresponding to six clones randomly chosen from a genomic library, are synthesized from the very beginning of development at a rate comparable to that observed late in development but that transcripts do not accumulate until after aggregation. The early- and late-synthesized mRNAs are identical in size and compete with each other for hybridization to the genomic clones. The early-synthesized mRNAs do not accumulate in the cytoplasm in the preaggregation stage because they are very unstable. Their stability, estimated from the kinetics of incorporation during continuous labeling with (32)P, increases by perhaps an order of magnitude in the postaggregation stage. We conclude that mRNA stabilization is the major controlling factor of the expression of these genes.

Specific cell-cell contacts are essential for induction of gene expression during differentiation of Dictyostelium discoideum

Postaggregation Dictyostelium discoideum cells contain 2000-3000 mRNA species that are absent from pre-aggregation cells. These aggregation-dependent sequences compose 30% of the mass of the late mRNA and represent the transcription products of an additional 11% of the single-copy genome. By analysis of mutants that are blocked at different stages of differentiation, we show that induction of expression of these genes is correlated with the formation of tight cell-cell contacts that resist EDTA. In particular, mutants that exhibit chemotaxis and aggregate to form loose mounds but do not form cell-cell contacts that resist EDTA fail to induce these late mRNA and protein species. By contrast, mutants that form normal contacts but progress no further through development do express the late mRNA species. Thus, interactions at the cell surface are involved in developmental induction of a large group of coregulated mRNAs. We have employed two independent assays for these developmentally regulated mRNAs: hybridization of gel-separated RNAs to cloned nuclear DNAs and hybridization of mRNA to a cDNA probe specific for the population of 2000-3000 regulated sequences.

Two Dictyostelium ribosomal proteins act as RNases for specific classes of mRNAs

Phosphorylation of ribosomal protein S6 leads to the stabilization of pre-spore specific mRNAs during development of Dictyostelium discoideum. The purification of S6 kinase has allowed the identification of protein S11 as the mRNase specific for pre-spore mRNAs. Methylation of ribosomal protein S31 leads to the destabilization of ribosomal protein mRNAs. The purification of S31 methyltransferase has allowed the identification of protein S29 as the mRNAse specific for ribosomal protein mRNAs.

Synthesis of ribosomal proteins in developing Dictyostelium discoideum cells is controlled by the methylation of proteins S24 and S31

Ribosomal protein mRNAs left over from growth are selectively excluded from polyribosomes in the first half of Dictyostelium discoideum development. This is due to the fact that they are sequestered by a class of free 40S ribosomal subunits, characterized by possessing a methylated S24 protein. At the time of formation of tight cell aggregates, the methylated S24 is substituted by an unmethylated S24, while protein S31 of the same or other 40S subunits becomes methylated. This leads to a rapid degradation of the ribosomal protein mRNAs.

Differential expression patterns of an acidic chitinase and a basic chitinase in the root nodule of Elaeagnus umbellata

Two cDNA clones encoding chitinase were isolated from a root nodule cDNA library of Elaeagnus umbellata by the hybridization-competition method. The two clones, EuNOD-CHT1 and EuNOD-CHT2, encode for 335 and 317 amino acid residues with the molecular mass of mature proteins being 33.3 and 31.1 kDa, respectively. The two chitinases showed similar protein structures consisting of four domains: hydrophobic signal peptide domain, cysteine-rich chitin-binding domain, hinge domain, and catalytic domain. The EuNOD-CHT1 gene showed similar expression levels in root nodules and leaves, with no detection of transcripts in the roots. The EuNOD-CHT2 gene was expressed at similarly high levels in the roots and root nodules, but at a very low level in the leaves. In situ hybridization showed that EuNOD-CHT1 transcripts were strongly detected in the meristem zone, but weakly detected in the outer cortex layer of the root nodule and in the uninfected cells of the fixation zone. On the other hand, EuNOD-CHT2 transcripts were strongly detected in the infected cells of the fixation zone and central vascular system, but weakly detected in the senescence zone. Our results suggest that the two chitinases may play different biological roles in the root nodule. EuNOD-CHT2 may be involved in a defense response against internal symbionts, external pathogens, or both, while EuNOD-CHT1 may be involved in normal plant development as well as in a defensive role against external pathogens.

Induction of ribosomal subunits misassembly by antisense RNAs to control cell growth

The assembly of ribosomal subunits starting from free ribosomal RNA and protein of Dictyostelium discoideum was induced in vitro in the presence of several oligoribonucleotides complementary to defined sequences of ribosomal RNA. The reconstituted particles had a full complement of ribosomal proteins, but did not function in an in vitro protein synthesis system and were disassembled following interaction with mRNA. The same result was obtained in vivo by fusing the oligodeossiribonucleotides coding for the selected oligoribonucleotides to the promoter of the gene coding for contact site A protein. This gene is expressed only in the first part of development. Transfected growing cells, transferred in developing buffer in the presence of pulses of cAMP, accumulated significant amounts of the oligoribonucleotides. When retransferred to the growth medium, they grew progressively more slowly, until their doubling time doubled, apparently due to the availability of a limiting amount of functional ribosomes. To avoid disassembly of misassembled subunits (G. Mangiarotti et al., 1997, J. Biol. Chem. 272, 27818-27822), two oligoribonucleotides complementary to sequences present at the 5' ends of pre-17S and pre-26S RNAs were also induced to accumulate during early development with the same technique. When transfected cells were retransferred to the growth medium, their rate of growth declined rapidly to zero and cells died, apparently because they were unable to disassemble misassembled ribosomal subunits and avoid their entry into polyribosomes. This technique to perturb protein synthesis, arrest cell growth, and cause cell suicide will be tested in abnormally growing animal cells.

Cell type specificity and mechanism of control of a gene may be reverted in different strains of Dictyostelium discoideum

Twelve genes which are expressed exclusively in pre-spore cells of Dictyostelium strain AX3 are expressed exclusively in pre-stalk cells of strain AX2. One gene has the opposite behavior: it is expressed in pre-stalk cells in AX3 and in pre-spore cells in AX2. The change in cell type specificity involves a change in the mechanism of control of gene expression. When they are expressed in pre-stalk cells, genes are controlled at the level of transcription, whilst in pre-spore cells, they are controlled at the level of mRNA stability. Genes expressed in pre-stalk cells in strain AX2, fused with an AX2 pre-spore specific promoter, become regulated at the level of mRNA stability. These findings indicate that at least a group of pre-stalk mRNAs possess the cis-destabilizing element typical of pre-spore mRNAs, though they are not destabilized in disaggregated cells. This is due to the fact that ribosomal protein S6, phosphorylation of which is responsible for controlling the stability of pre-spore mRNAs, is not dephosphorylated in disaggregated pre-stalk cells. These cells lack an S6 phosphatase activity which has been purified from disaggregated pre-spore cells.

Application of an improved cDNA competition technique to identify prostate cancer-associated gene

A technique to improve cDNA library screening was developed by using mixed probes derived from two closely related cDNA populations of high-metastatic MAT-LyLu and low-metastatic AT-1 Dunning R3227 rat prostate cancer sublines. The technique required the generation of a cDNA library from each subline followed by polymerase chain reaction (PCR) amplification of the cDNA insert population. The PCR products derived from the first library were radiolabeled and mixed with an excess amount of PCR products from the second library. The mixture and an excess amount of both the lambda and pBluescript DNA were used as a probe to screen the first cDNA library. This mixed probe (designated the competition probe) differentially cross-hybridized with the plaque lift of the screened first cDNA library. Weak radioactive signals indicated the cross-hybridization of cDNA sequences common to the competition probe mixture and the first cDNA library, whereas strong signals implied unhybridized unique or abundant cDNA sequences in the first cDNA library. The reproducibility of this technique was confirmed by showing that the full-length cDNA clones were associated with the phenotype of the screened first cell line. The isolated clones were characterized as rat nucleolar protein, rat mitochondrial genes coding for 16S and 12S rRNAs, and rat tRNAs specific for valine and phenyl-alanine. This result is consistent with the fact that the first cell line, MAT-LyLu, is metabolically more active than are AT-1 cells because of higher gene dosage or amplification of nucleolar and mitochondrial RNA and its associated genes. Another clone which had a strong signal represented a novel gene associated with the MAT-LyLu cancer phenotype.

The phosphorylation of protein S6 modulates the interaction of the 40 S ribosomal subunit with the 5'-untranslated region of a dictyostelium pre-spore-specific mRNA and controls its stability

AC914 mRNA, a pre-spore-specific mRNA that accumulates only in the post-aggregation stage of development, is transcribed constitutively as shown by nuclear run-off experiments and by fusing its promoter to the luciferase reporter gene. The same mRNA disappears quickly from disaggregated cells. If the 5'-untranslated region (5'UTR) of the constitutively expressed Actin 15 mRNA is substituted for the 5'UTR of AC914 mRNA, this can no longer be destabilized and accumulates both in growing and disaggregated cells. If the 5'UTR of AC914 mRNA is substituted for the 5'UTR of Actin 15 mRNA, the latter accumulates only in aggregated cells. Pactamycin, but not other inhibitors of protein synthesis, prevents AC914 mRNA from being destabilized in disaggregated cells, suggesting a role of 40 S subunits in the destabilization. This has been confirmed by using an in vitro system in which the in vivo stability of different mRNAs is reproduced. A protein kinase A-dependent phosphorylation of ribosomal protein S6 determines whether 40 S subunits are capable or not of destabilizing AC914 mRNA in the in vitro system.

Reconstitution of functional eukaryotic ribosomes from Dictyostelium discoideum ribosomal proteins and RNA

40 and 60 S ribosomal subunits have been reconstituted in vitro from purified ribosomal RNA and ribosomal proteins of Dictyostelium discoideum. The functionality of the reconstituted ribosomes was demonstrated in in vitro mRNA-directed protein synthesis. The reassembly proceeded well with immature precursors of ribosomal RNA but poorly if at all with mature cytoplasmic RNA species. Reassembly also required a preparation of small nuclear RNA(s), acting as morphopoietic factor(s).

Subtractive cDNA cloning as a tool to analyse secondary effects of a muscle disease. Characterization of affected genes in the myotonic ADR mouse

In myotonic ADR mice that are homozygous for a defect in the muscular chloride channel gene adr/Clc-1, the hyperexcitability of fast muscles is associated with secondary changes in gene expression and fibre type composition. cDNA clones derived from a set of genes down regulated in fast muscles of the myotonic ADR mouse were isolated by a subtractive cloning procedure. A total of 1200 clones were analysed for high expression in fast muscle of wild type and low expression in mutant mouse. Differential transcript levels were verified by northern blot hybridizations. The identities of the corresponding transcripts were determined by sequencing as myosin heavy chain IIB, alpha-tropomyosin, troponin C, a Ca2+ ATPase and parvalbumin mRNAs. Of these, mRNAs for parvalbumin and myosin heavy chain IIB were drastically downregulated in myotonic muscle (to < 10% of control). A full length cDNA clone for skeletal muscle alpha-tropomyosin was homologous to the mouse fibroblast tropomyosin isoform 2, except for the portion encoding the alpha-tropomyosin specific amino acids 258-284. A cDNA derived from the 1100 nucleotide parvalbumin transcript was cloned and the sequence for the as yet unknown 3' extended trailer, generated by alternative polyadenylation, was determined.

A survey of transcripts expressed specifically in root nodules of broadbean (Vicia faba L.)

More than 600 potentially nodule-specific clones have been detected by differential hybridization of a broadbean cDNA library constructed from root nodule poly(A)+ RNA. These isolated cDNAs belong to at least 28 different clone groups containing cross-hybridizing sequences. The number of clones within a clone group varies from about 200 to only one single clone. Northern hybridization experiments revealed nodule-specific transcripts for 14 clone groups and markedly nodule-enhanced transcripts for another 7 clone groups. Sequence homologies indicate that three transcript sequences code for different leghemoglobins. Two other transcripts encode a nodule-specific sucrose synthase and a nodule-enhanced asparagine synthetase, respectively. Four deduced gene products are proline-rich, two of them being the homologues of PsENOD2 and PsENOD12. The third proline-rich protein (PRP) is composed of similar amino acid repeats as the nodule-specific PsENOD12 but is expressed in nodules and roots in comparable amounts. The fourth PRP is a nodule-enhanced extensin-type protein built up by Ser-Pro4 repeats. Two further nodule-specific transcripts encode gene products showing some similarity to structural glycine-rich proteins. Additionally, transcripts could be identified for broadbean homologues of the nodulins MsNOD25, PsENOD3 and PsENOD5 and transcripts specifying a nodule-enhanced lipoxygenase and a translation elongation factor EF-1 alpha, which is expressed in all broadbean tissues tested.

Molecular approaches for analyzing differential gene expression: differential cDNA library construction and screening

Complementary deoxyribonucleic acid (cDNA) libraries can be used as a means to isolate and identify cell-specific messenger ribonucleic acid (mRNA) sequences. The basic elements of cDNA library construction and screening are reviewed in the context of analyzing differentially expressed mRNAs. A brief overview of the recombinant DNA systems applied to cDNA library construction and the principles of screening cDNA libraries by plaque hybridization are provided. Methods for comparing mRNA populations by differential screening and by competition hybridization are discussed, and methods for constructing subtracted cDNA libraries, enriched in differentially expressed sequences, are presented. Also reviewed are the analysis of differentially expressed cDNAs by Southern and Northern hybridization, RNase protection, polymerase chain reaction, and sequencing.

Developmental regulation of cell-type-enriched mRNAs in Dictyostelium discoideum

We describe sixteen new families of cDNA clones representing mRNAs that are expressed preferentially in either prespore or prestalk cells during development of Dictyostelium discoideum and two new mRNAs that are expressed in a non-cell-type-specific manner. None of the prespore-enriched mRNAs are detectable in Dictyostelium cells until 13-15 h of development but then they increase dramatically and peak at 18-22 h. Upon dissociation of developing aggregates, all these mRNAs rapidly decay to low levels. In marked contrast to data presented for prespore genes by other workers, cyclic AMP either has no effect on the mRNA levels in dissociated cells or is only weakly effective in restoring normal expression. A prestalk-enriched mRNA examined, 5G mRNA, is similarly expressed late in development but is also expressed in vegetative cells. The level of 5G mRNA is only moderately affected by cell disaggregation.

Gene cloning using cDNA libraries in a differential competition hybridization strategy: application to cloning XP-A related genes

A competition hybridization strategy using size-cut cDNA libraries as both probe and competitor was designed for the cloning of genes whose mRNAs are either regulated transcriptionally or vary in abundance as a function of cell line or cell cycle. We used this strategy to construct cDNA libraries from a particular size fraction of mRNA from three members of a xeroderma pigmentosum (XP), complementation group A family. Size-cut cDNA libraries derived from the father's, mother's, and child's fibroblast cell line were used in a competition scheme to screen two lambda gt11 human cDNA libraries. Of the 15 positive lambda gt11 clones which have been characterized, at least 14 clones represent the same gene which is present in greater abundance in both the mother and father XP obligate heterozygotes relative to the homozygous affected child.

A T cell- and natural killer cell-specific, trypsin-like serine protease. Implications of a cytolytic cascade

A new trypsin-like serine protease was cloned from both a murine cytotoxic T lymphocyte and a human PHA-stimulated peripheral blood lymphocyte cDNA library. In both the mouse and human system, this transcript had a T cell- and NK-specific distribution, being detected in cytotoxic T lymphocytes (CTL), some T-helper clones, and NK, but not in a variety of normal tissues. T-cell activation with Con A plus IL-2 induced mouse spleen cells to express this gene with kinetics correlating with the acquisition of cytolytic capacity. Both the mouse and human nucleotide sequences of this gene encoded an amino acid sequence with 25-40% identity to members of the serine protease family. The active-site "charge-relay" residues (His-57, Asp-102, and Ser-195 of the chymotrypsin numbering system) are conserved, as well as the trypsin-specific Asp (position 189 in trypsin). We reviewed the evidence of this serine protease's role in lymphocyte lysis and proposed a "lytic cascade." We discussed the biological and clinical implications of a cascade, proposing these enzymes as markers for cytolytic cells and as targets for rational drug therapy. Genetic and acquired deficits in the lethal hit-delivery system are considered as a basis for approaching some immunodeficiency states, including severe EBV infections, T-gamma leukemias, and T8+ lymphocytosis syndromes.

Changes during differentiation in requirements for cAMP for expression of cell-type-specific mRNAs in the cellular slime mold, Dictyostelium discoideum

A number of genes encoding developmentally regulated mRNAs in the cellular slime mold, Dictyostelium discoideum, have been described. Many of these are regulated by cAMP. Analysis of the earliest time at which elevated levels of cAMP can induce the expression of these mRNAs reveals a more complex pattern of regulation in which genes change in their ability to be induced in response to cAMP with developmental stage. A prestalk mRNA (C1/D11) previously thought not be regulated by elevated levels of cAMP is inducible by cAMP between aggregation and loose mound stage; later in development its expression becomes independent of elevated cAMP. The early prespore genes (prespore class I) also show two modes of regulation; early in development they are induced independently of continuous elevated levels of cAMP, while later in development their expression is dependent upon elevated cAMP. The period during development when the prestalk genes are cAMP inducible precedes by 2 hr the first time at which either the early prespore class I or late prespore class II mRNAs are inducible by continuous elevated levels of cAMP. Previous analysis of these mRNAs has been carried out using Dictyostelium cells grown axenically. In this report we have studied the developmental expression of these mRNAs in cells grown on bacteria. A substantial shutoff of the class I prestalk and early prespore (class I) mRNAs not seen in axenically grown cells is observed when bacterially grown cells are plated for development. Less than 10% of the maximal level of these mRNAs remains in the cells at the time of mature spore and stalk differentiation. Additionally, in the bacterially grown cells two distinct patterns of developmental regulation are observed for mRNAs which in axenically growing cells appear to be constitutively expressed throughout growth and development.

Cloning of a cDNA for a T cell-specific serine protease from a cytotoxic T lymphocyte

A new serine protease was encoded by a clone isolated from a murine cytotoxic T-lymphocyte complementary DNA library by an RNA-hybridization competition protocol. Complementary transcripts were detected in cytotoxic T lymphocytes, spleen cells from nude mice, a rat natural killer cell leukemia, and in two of eight T-helper clones (both cytotoxic), but not in normal mouse kidney, liver, spleen, or thymus, nor in several tested T- and B-cell tumors. T-cell activation with concanavalin A plus interleukin-2 induced spleen cells to express this gene with kinetics correlating with the acquisition of cytolytic capacity. The nucleotide sequence of this gene encoded an amino acid sequence of approximately 25,700 daltons, with 25 to 35 percent identity to members of the serine protease family. The active site "charge-relay" residues (His57, Asp102, and Ser195 of the chymotrypsin numbering system) are conserved, as well as the trypsin-specific Asp (position 189 in trypsin). A Southern blot analysis indicated that this gene is conserved in humans, mouse, and chicken. This serine protease may have a role in lymphocyte lysis and a "lytic cascade."

Isolation of genes preferentially expressed during Bacillis subtilis spore outgrowth

From the Charon 4A library of Ferrari et al (J. Bacteriol. 146:430-432, 1981) we isolated three genes involved in Bacillus subtilis spore outgrowth by screening the library by hybridization with labeled RNA from outgrowing spores in the presence of an excess of unlabeled vegetative RNA. Hybridization competition experiments with purified clones showed that the clones contained sequences that were transcribed only during spore outgrowth or preferentially during spore outgrowth. Fragments of the cloned DNAs were subcloned in plasmid pJH101, and by using plasmid integration and PBS1 transduction the chromosomal loci were mapped. The three loci which we mapped are outG and outH, which are located between polC and dnaA, and outI, which is located near pycA. Using the cloned DNAs and derived plasmids in dot hybridization experiments with RNA extracted from cells at different developmental stages, we defined for two clones a region that is transcribed only during the outgrowth phase.

Structure of the promoter of the Dictyostelium discoideum prespore EB4 gene

EB4 is one of several cloned cDNAs that is expressed as mRNA only after the aggregation stage of Dictyostelium discoideum differentiation and exclusively in prespore and spore cells (E. Barklis and H. F. Lodish, Cell 32:1139-1148, 1983). We have isolated the unique genome fragment corresponding to the 5' portion of the EB4 message and the EB4 promoter. The EB4 transcript has an unusually long, G + C-rich, 5' noncoding region, but initiates at several start sites within a region of DNA that is 96% A + T. The sequence GTGGTGG, along with slight variations, occurs several times in the promoter. We have used the EB4 promoter to drive the transcription of an EB4/beta-galactosidase fusion transcript in yeast cells. Although the cap sites of the fused transcript in yeast cells are located in the region where multiple EB4 transcripts are initiated in Dictyostelium, the unregulated expression of the fusion transcript in yeast does not mimic the normal regulated pattern of EB4 mRNA expression in D. discoideum.

Specific regulation of transcription of the discoidin gene family in Dictyostelium discoideum

Dictyostelium discoideum strains that carry the dis mutations fail to express the family of developmentally regulated discoidin lectin genes during morphogenesis. We show here that this absence of discoidin lectin expression is due to the failure to transcribe the discoidin genes. Furthermore, the dis mutations appear to affect only discoidin expression and not the expression of other proteins during development, as assessed by a two-dimensional gel analysis of pulse-labeled proteins and by the accumulation of developmentally regulated enzymes. The dis mutations appear to define trans-acting regulatory loci, the products of which act at the transcriptional level to control specifically the developmental expression of the discoidin gene family.

Blastoderm-differential and blastoderm-specific genes of Drosophila melanogaster

We have isolated, by molecular cloning, genes expressed differentially at the blastoderm stage of Drosophila melanogaster. Two of the blastoderm-differential genes are reexpressed at later stages, and map to single chromosomal loci 95C and 99E. The sequence at 99E is that encoding the myosin light chain 2. Two other blastoderm-differential sequences are members of multigene families (one of which is B104, or roo) and map to multiple dispersed chromosomal loci. A gastrula-differential sequence was found which maps to 71A. Most significantly, we have identified three genes encoding transcripts expressed uniquely at the blastoderm stage; these map to single chromosomal loci: 25D3, 75C, and 99D4-8. At least some of the blastoderm-differential and blastoderm-specific loci appear to be distinct from loci involved in embryonic pattern formation that have been identified in recent genetic "saturation" screens. The procedure of identifying genes specific to the blastoderm stage may thus allow the identification of genes, not previously identified by classical genetic techniques, that are involved in important embryonic processes.

Structure of the promoter of the Dictyostelium discoideum prespore EB4 gene

EB4 is one of several cloned cDNAs that is expressed as mRNA only after the aggregation stage of Dictyostelium discoideum differentiation and exclusively in prespore and spore cells (E. Barklis and H. F. Lodish, Cell 32:1139-1148, 1983). We have isolated the unique genome fragment corresponding to the 5' portion of the EB4 message and the EB4 promoter. The EB4 transcript has an unusually long, G + C-rich, 5' noncoding region, but initiates at several start sites within a region of DNA that is 96% A + T. The sequence GTGGTGG, along with slight variations, occurs several times in the promoter. We have used the EB4 promoter to drive the transcription of an EB4/beta-galactosidase fusion transcript in yeast cells. Although the cap sites of the fused transcript in yeast cells are located in the region where multiple EB4 transcripts are initiated in Dictyostelium, the unregulated expression of the fusion transcript in yeast does not mimic the normal regulated pattern of EB4 mRNA expression in D. discoideum.

Specific regulation of transcription of the discoidin gene family in Dictyostelium discoideum

Dictyostelium discoideum strains that carry the dis mutations fail to express the family of developmentally regulated discoidin lectin genes during morphogenesis. We show here that this absence of discoidin lectin expression is due to the failure to transcribe the discoidin genes. Furthermore, the dis mutations appear to affect only discoidin expression and not the expression of other proteins during development, as assessed by a two-dimensional gel analysis of pulse-labeled proteins and by the accumulation of developmentally regulated enzymes. The dis mutations appear to define trans-acting regulatory loci, the products of which act at the transcriptional level to control specifically the developmental expression of the discoidin gene family.

A developmentally regulated cysteine proteinase in Dictyostelium discoideum

We have determined the sequence of a Dictyostelium mRNA encoding a protein with a high degree of homology to plant and animal cysteine proteinases. The degree of homology is highest in the region of the cysteine residue which is transiently acylated during peptide hydrolysis but all other residues known to be important in catalysis are also conserved. We have named this protein cysteine proteinase 1. There is a hydrophobic signal peptide of 18 amino acids and an additional 99 amino acids at the N terminus, which are not present in other cysteine proteases and which may be cleaved off during processing of the enzyme. There is a single copy of the gene in the Dictyostelium genome. The cysteine proteinase 1 mRNA is absent from growing cells and from cells isolated during the first 6 h of development but it constitutes approximately 1% of cellular mRNA by 10-12 h of development. During the development of Dictyostelium a major fraction of cellular protein is degraded to provide amino acids and a source of energy. Cysteine proteinase 1 may play a role in this auto-digestion.

Identification and expression in Escherichia coli of merozoite stage-specific genes of the human malarial parasite Plasmodium falciparum

The key steps in the development of a malaria vaccine through gene cloning are the identification of the proteins involved in host protective immunity and the cloning, identification, and expression of the genes coding for these proteins. Recent data have indicated that certain proteins synthesized at the late schizont-merozoite stage of Plasmodium falciparum play a major role in malaria immunity. This paper reports the identification, in a cDNA library, of recombinant clones corresponding to genes expressed specifically during the late schizont-merozoite stage of P. falciparum development. The 132 cDNA clones thus identified out of 10,000 were found to correspond to only 12 different genes, probably representing most of the major schizont-merozoite specific genes. The stage-specific cDNAs can be efficiently expressed in Escherichia coli cells. The protein products of some of these clones are recognized by monoclonal antibodies specific for late schizont-merozoite proteins. We conclude that only a small set of genes is specifically induced in the schizont-merozoite stage and that the stage-specific cDNA clones we have isolated are very likely to include the genes coding for the immunologically relevant proteins of P. falciparum.

Dictyostelium transposable element DIRS-1 has 350-base-pair inverted terminal repeats that contain a heat shock promoter

DIRS-1 is a 4.7-kilobase-pair repetitive and apparently transposable Dictyostelium genetic element that is transcribed during differentiation or after heat shock. The terminal regions of DIRS-1 are inverted repeats of 330 base pairs. The repeats are highly conserved both within a given element as well as between different members of the family (less than 10% divergence). At the distal end of all left repeats is a 32-nucleotide sequence composed almost entirely of A and T residues. In addition to this 32-base A + T sequence, the distal region of all right repeats is extended by a 28-base-pair A + T-rich sequence that is identical in all copies. The sequences flanking each DIRS-1 sequence are completely dissimilar, and there appears to be no duplication of the genomic DNA sequence at the presumed point of DIRS-1 insertion. The terminal repeats can also be found interspersed in the genome independently of the complete element. In addition, the terminal repeats carry a 15-nucleotide sequence that greatly resembles the Drosophila consensus heat shock promoter and may be involved in the transcriptional induction of the DIRS-1 sequences.

Proteins related to the mouse L-cell major heat shock protein are synthesized in the absence of heat shock gene expression

Heat shock of mouse L cells induces the synthesis of two polypeptides of Mrs 68,000 and 89,000. Using a fragment of a cloned gene encoding the Drosophila melanogaster Mr 70,000 heat shock protein (hsp70), we have shown that this protein has been highly conserved during eukaryotic evolution. We extended this observation by probing at low stringency for the expression in mouse L cells of RNA homologous to the Drosophila hsp70 gene. In addition to the RNA encoding the inducible Mr 68,000 heat shock protein (hsp68), there are mouse mRNAs encoding proteins of Mrs 70,000 and 74,000 that are homologous to the Drosophila hsp70 gene. The Mrs 70,000 and 74,000 proteins and their mRNAs are abundant components of unstressed mouse L cells. These constituitively expressed proteins are unique polypeptides in contrast to the several isoelectric point variants of the inducible hsp68. We do not detect hsp68 or its mRNA in unstressed L cells. In addition to the mRNAs corresponding to hsp68 and the Mrs 74,000 and 70,000 proteins, we detect a fourth RNA homologous to the Drosophila hsp70 gene but whose protein product has not been identified. Our results suggest that the hsp68 gene of mouse L cells is a member of a multigene family and that the individual family members are distinguishable by their degree of similarity but show differences in the regulation of their expression.

Isolation of DNA sequences preferentially expressed during sporulation in Saccharomyces cerevisiae

A differential hybridization screen has been used to identify genes cloned from the yeast Saccharomyces cerevisiae that are expressed preferentially during sporulation. Duplicate copies of a partial Sau3A yeast DNA library prepared in the vector pBR322 were hybridized with radioactive cDNA probes representing the mRNA populations of sporulating a alpha cells and asporogenous alpha alpha cells at various times after transfer to sporulation medium. Thirty-eight clones showed an enhanced hybridization signal with the a alpha sporulation probe relative to the alpha alpha control cDNA probe. A comparison of the array of fragments produced by restriction endonuclease digestion of these plasmids suggested that 15 different sequences had been cloned. An RNA blot analysis using these cloned DNAs to probe RNAs purified from aa, a alpha, and alpha alpha cells harvested either during vegetative growth or at 10 h after transfer to sporulation medium indicated that 14 different sporulation-specific genes had been identified. Transcripts complementary to these genes are present only in a alpha cells after transfer to sporulation medium. Three of these clones contain two sporulation-specific genes. Three genes have been identified that are expressed in all cell types during vegetative growth and only in a alpha cells in sporulation medium.

Molecular cloning of a gene abundantly expressed during fruiting body initiation in Schizophyllum commune

Complementary DNA was synthesized on polyadenylated RNA from a dikaryotic mycelium of the basidiomycete Schizophyllum commune bearing fruiting body initials. The complementary DNA was cloned into the PstI site of pBR327 by the deoxyguanidylate-deoxycytidylate tailing approach. After transformation into Escherichia coli cells, a differential screening was performed by colony hybridization with complementary [32P]DNA made on the RNAs of the monokaryon and dikaryon strains. Two clones were selected for further analysis by Northern blotting and hybrid release translation. Clone 1D10 hybridized with an mRNA of 775 nucleotides, coding for a polypeptide with an Mr of 15,000. Although this RNA was present in both monokaryotic and dikaryotic mycelia, its concentration appeared to change considerably over time and with different cultivation conditions. This mRNA is probably the most abundantly expressed sequence in S. commune. Clone 1G2 and its homologs hybridized with an mRNA of 650 nucleotides, coding for a polypeptide with an Mr of 13,000. This gene was exclusively expressed in the dikaryon strain. In liquid-grown cultures, the concentration of this mRNA was low but increased ca. 20-fold during the establishment of fruiting body primordia. A chromosomal fragment of 9 kilobase pairs which contained the 1G2 gene was cloned into pBR327 and used as a probe in Northern blot hybridization. It was found that surrounding sequences were not expressed at the same time or to the same extent as the 1G2 gene.

Characterization of cDNA clones specific for sequences developmentally regulated during Dictyostelium discoideum spore germination

Spore germination in the slime mold Dictyostelium discoideum was used as a model to study the developmental regulation of protein and mRNA synthesis. Changes in the synthesis of these macromolecules occur during the transition from dormant spore to amoebae. The study of the mechanisms which regulate the quantity and quality of protein synthesis can best be accomplished with cloned genes. cDNA clones which hybridized primarily with mRNAs from only spores or germinating spores and not with growing amoebae were collected. Three such clones, denoted pLK109, pLK229, and pRK270, were isolated and had inserts of approximately 500, 1,200, and 690 base pairs, respectively. Southern blot hybridization experiments suggested that each of the genes is present in multiple copies in the D. discoideum genome. RNA blot hybridizations were performed to determine the sizes of the respective mRNAs and their developmental regulation. The mRNA that hybridized to pLK109 DNA was present predominantly in spores and at 1 h after germination but was absent in growing amoebae. Its concentration dramatically dropped at 3 h. The mRNA present in spores is apparently larger (approximately 0.5 kilobase) than in the later stages of germination (0.4 kilobase), indicating processing of the RNA during germination. The mRNA that hybridized to pLK229 DNA was approximately 1.0 kilobase and was present in very low amounts during growth. Its concentration rose until 1 h after spore germination and decreased thereafter. pRK270-specific RNA was approximately 2.7 kilobases and was found predominantly at 1 h after germination. It was present in lower concentrations at 2 and 3 h after germination and was absent in spores and amoebae. In vitro translation of mRNA selected from 1-h polyadenylated RNA which was hybridized to pLK109 or pLK229 DNA gave proteins of molecular weights consistent with the sizes of the mRNAs as determined by the RNA blot analysis.

Isolation of DNA sequences preferentially expressed during sporulation in Saccharomyces cerevisiae

A differential hybridization screen has been used to identify genes cloned from the yeast Saccharomyces cerevisiae that are expressed preferentially during sporulation. Duplicate copies of a partial Sau3A yeast DNA library prepared in the vector pBR322 were hybridized with radioactive cDNA probes representing the mRNA populations of sporulating a alpha cells and asporogenous alpha alpha cells at various times after transfer to sporulation medium. Thirty-eight clones showed an enhanced hybridization signal with the a alpha sporulation probe relative to the alpha alpha control cDNA probe. A comparison of the array of fragments produced by restriction endonuclease digestion of these plasmids suggested that 15 different sequences had been cloned. An RNA blot analysis using these cloned DNAs to probe RNAs purified from aa, a alpha, and alpha alpha cells harvested either during vegetative growth or at 10 h after transfer to sporulation medium indicated that 14 different sporulation-specific genes had been identified. Transcripts complementary to these genes are present only in a alpha cells after transfer to sporulation medium. Three of these clones contain two sporulation-specific genes. Three genes have been identified that are expressed in all cell types during vegetative growth and only in a alpha cells in sporulation medium.

Efficient transformation of Dictyostelium discoideum amoebae

We have transformed Dictyostelium discoideum amoebae by using derivatives of a plasmid, pAG60, which was designed for transformation of mammalian cells. The plasmid carries the promoter region of the herpes simplex virus type 1 thymidine kinase gene linked to the bacterial gene kan, which codes for the enzyme aminoglycoside 3'-phosphotransferase. kan is derived from the Tn5 transposon. Expression of the phosphotransferase permits direct selection of transformed cells by their resistance to the antibiotic G-418. pAG60 is incapable of transforming D. discoideum but is made transformation proficient by cloning D. discoideum sequences into the tetracycline resistance gene. The majority of transformed cells grow and develop normally and differentiate to give G-418-resistant spores. These transformants are unstable and rapidly lose their G-418-resistance during growth in the absence of antibiotic selection. Southern blots show that these unstable G-418-resistant transformants carry the pBR322 and kan sequences of pAG60. The pAG60-D. discoideum recombinant plasmids used for transformation were constructed in a way that might make them mutagenic. We have isolated several developmental mutants after transformation of D. discoideum with libraries of pAG60-D. discoideum recombinant plasmids. These mutants are G-418 resistant and carry pAG60 in their nuclear DNA. We recovered a pAG60-D. discoideum recombinant plasmid from several developmental mutants. This plasmid transforms D. discoideum at an elevated frequency and integrates into the nuclear genome. We speculate that integration can result in insertional inactivation of genes that are essential for differentiation but not for growth. Mutagenic transformation occurred only if the transforming plasmid had homology with D. discoideum nuclear DNA. A mammalian cell transformation vector, pSV2-neo, carried no D. discoideum sequences and was able to transform. However, pSV2-neo transformation was not mutagenic. These results suggest that direct inactivation and recovery of genes that are essential for differentiation of D. discoideum will be possible.

Efficient transformation of Dictyostelium discoideum amoebae

We have transformed Dictyostelium discoideum amoebae by using derivatives of a plasmid, pAG60, which was designed for transformation of mammalian cells. The plasmid carries the promoter region of the herpes simplex virus type 1 thymidine kinase gene linked to the bacterial gene kan, which codes for the enzyme aminoglycoside 3'-phosphotransferase. kan is derived from the Tn5 transposon. Expression of the phosphotransferase permits direct selection of transformed cells by their resistance to the antibiotic G-418. pAG60 is incapable of transforming D. discoideum but is made transformation proficient by cloning D. discoideum sequences into the tetracycline resistance gene. The majority of transformed cells grow and develop normally and differentiate to give G-418-resistant spores. These transformants are unstable and rapidly lose their G-418-resistance during growth in the absence of antibiotic selection. Southern blots show that these unstable G-418-resistant transformants carry the pBR322 and kan sequences of pAG60. The pAG60-D. discoideum recombinant plasmids used for transformation were constructed in a way that might make them mutagenic. We have isolated several developmental mutants after transformation of D. discoideum with libraries of pAG60-D. discoideum recombinant plasmids. These mutants are G-418 resistant and carry pAG60 in their nuclear DNA. We recovered a pAG60-D. discoideum recombinant plasmid from several developmental mutants. This plasmid transforms D. discoideum at an elevated frequency and integrates into the nuclear genome. We speculate that integration can result in insertional inactivation of genes that are essential for differentiation but not for growth. Mutagenic transformation occurred only if the transforming plasmid had homology with D. discoideum nuclear DNA. A mammalian cell transformation vector, pSV2-neo, carried no D. discoideum sequences and was able to transform. However, pSV2-neo transformation was not mutagenic. These results suggest that direct inactivation and recovery of genes that are essential for differentiation of D. discoideum will be possible.

Mouse and Drosophila genes encoding the major heat shock protein (hsp70) are highly conserved

We used a cloned Drosophila melanogaster hsp70 gene to hybrid-select heat shock-induced mouse mRNA and showed that this mRNA encodes the major mouse heat shock protein. This result suggests that the sequence of the hsp70 gene(s) is highly conserved.

Different mRNAs have different nuclear transit times in Dictyostelium discoideum aggregates

Nuclear processing of mRNA precursors in differentiating multicellular Dictyostelium discoideum aggregates is markedly slower than in growing amoebae. Thus, we have been able to determine the time of nuclear processing of individual mRNA species in postaggregating cells by following the incorporation of 32PO4 into nuclear and cytoplasmic RNA complementary to cloned cDNAs. Precursors of mRNAs synthesized during both growth and differentiation remain in the nucleus for about 25 to 60 min. By contrast, typical mRNAs which are synthesized only by postaggregative cells have nuclear processing times between 50 and 100 min. Depending on the particular mRNA, between 20 and 60% of nuclear transcripts are converted into cytoplasmic mRNA. A third class of mRNAs are transcribed from a set of repetitive DNA segments and are expressed predominantly during differentiation. Nuclear precursors of these mRNAs are extensively degraded within the nucleus or very rapidly after transport to the cytoplasm. Those sequences that are stable in the cytoplasm exit from the nucleus only after a lag of over 2 h. Thus, mRNAs encoded by different genes that are subject to different types of developmental controls display different times of transit to the cytoplasm and different efficiencies of nuclear processing. Differential nuclear processing may contribute to the regulation of the level of individual cytoplasmic mRNAs.

Genomic organization of the genes coding for the six main histones of the chicken: complete sequence of the H5 gene

The organization of the genes coding for histones in the chicken has been examined, with special reference to that coding for the tissue-specific, developmentally regulated histone H5. Two recombinant phages containing sequences complementary to cloned H5 cDNA have been isolated from a genomic chicken library. The clones have been characterized by heteroduplex formation, restriction nuclease analysis, hybridization to cloned homologous histone gene probes, and DNA sequencing. Hybridization to genomic DNA has shown that there is only one copy of the H5 gene per haploid genome, whereas there are six to 11 copies of the genes for the other histones. Examination of 29 X 10(3) base-pairs of DNA sequences flanking the H5 gene has revealed the absence of any other histone genes which, although not tandemly reiterated, for the most part appear to reside in loosely organized clusters. The complete DNA sequence of the H5 gene and flanking regions, as well as the mapping of the 5'-end of its messenger RNA by primer extension with AMV reverse transcriptase, has shown that the gene has no introns and little homology to other histone genes, including those for H1.

Characterization of cDNA clones specific for sequences developmentally regulated during Dictyostelium discoideum spore germination

Spore germination in the slime mold Dictyostelium discoideum was used as a model to study the developmental regulation of protein and mRNA synthesis. Changes in the synthesis of these macromolecules occur during the transition from dormant spore to amoebae. The study of the mechanisms which regulate the quantity and quality of protein synthesis can best be accomplished with cloned genes. cDNA clones which hybridized primarily with mRNAs from only spores or germinating spores and not with growing amoebae were collected. Three such clones, denoted pLK109, pLK229, and pRK270, were isolated and had inserts of approximately 500, 1,200, and 690 base pairs, respectively. Southern blot hybridization experiments suggested that each of the genes is present in multiple copies in the D. discoideum genome. RNA blot hybridizations were performed to determine the sizes of the respective mRNAs and their developmental regulation. The mRNA that hybridized to pLK109 DNA was present predominantly in spores and at 1 h after germination but was absent in growing amoebae. Its concentration dramatically dropped at 3 h. The mRNA present in spores is apparently larger (approximately 0.5 kilobase) than in the later stages of germination (0.4 kilobase), indicating processing of the RNA during germination. The mRNA that hybridized to pLK229 DNA was approximately 1.0 kilobase and was present in very low amounts during growth. Its concentration rose until 1 h after spore germination and decreased thereafter. pRK270-specific RNA was approximately 2.7 kilobases and was found predominantly at 1 h after germination. It was present in lower concentrations at 2 and 3 h after germination and was absent in spores and amoebae. In vitro translation of mRNA selected from 1-h polyadenylated RNA which was hybridized to pLK109 or pLK229 DNA gave proteins of molecular weights consistent with the sizes of the mRNAs as determined by the RNA blot analysis.

Molecular cloning of five individual stage- and tissue-specific mRNA sequences from sea urchin pluteus embryos

Five developmentally regulated sea urchin mRNA sequences which increase in abundance between the blastula and pluteus stages of development were isolated by molecular cloning of cDNA. The regulated sequences all appeared in moderately abundant mRNA molecules of pluteus cells and represented 4% of the clones tested. There were no regulated sequences detected in the 40% of the clones which hybridized to the most abundant mRNA, and the screening procedures were inadequate to detect possible regulation in the 20 to 30% of the clones presumably derived from rare-class mRNA. The reaction of 32P[cDNA] from blastula and pluteus mRNA to dots of the cloned DNAs on nitrocellulose filters indicated that the mRNAs complementary to the different cloned pluteus-specific sequences were between 3- and 47-fold more prevalent at the pluteus stage than at the blastula stage. Polyadenylated RNA from different developmental stages was transferred from electrophoretic gels to nitrocellulose filters and reacted to the different cloned sequences. The regulated mRNAs were undetectable in the RNA of 3-h embryos, became evident at the hatching blastula stage, and reached a maximum in abundance by the gastrula or pluteus stage. Certain of the clones reacted to two sizes of mRNA which did not vary coordinately with development. Transfers of RNA isolated from each of the three cell layers of pluteus embryos that were reacted to the cloned sequences revealed that two of the sequences were found in the mRNA of all three layers, two were ectoderm specific, and one was endoderm specific. Four of the regulated sequences were complementary to one or two major bands and one to at least 50 bands on Southern transfers of restriction endonuclease-digested total sea urchin DNA.

Different mRNAs have different nuclear transit times in Dictyostelium discoideum aggregates

Nuclear processing of mRNA precursors in differentiating multicellular Dictyostelium discoideum aggregates is markedly slower than in growing amoebae. Thus, we have been able to determine the time of nuclear processing of individual mRNA species in postaggregating cells by following the incorporation of 32PO4 into nuclear and cytoplasmic RNA complementary to cloned cDNAs. Precursors of mRNAs synthesized during both growth and differentiation remain in the nucleus for about 25 to 60 min. By contrast, typical mRNAs which are synthesized only by postaggregative cells have nuclear processing times between 50 and 100 min. Depending on the particular mRNA, between 20 and 60% of nuclear transcripts are converted into cytoplasmic mRNA. A third class of mRNAs are transcribed from a set of repetitive DNA segments and are expressed predominantly during differentiation. Nuclear precursors of these mRNAs are extensively degraded within the nucleus or very rapidly after transport to the cytoplasm. Those sequences that are stable in the cytoplasm exit from the nucleus only after a lag of over 2 h. Thus, mRNAs encoded by different genes that are subject to different types of developmental controls display different times of transit to the cytoplasm and different efficiencies of nuclear processing. Differential nuclear processing may contribute to the regulation of the level of individual cytoplasmic mRNAs.