The multiple subunits of discoidin I are encoded by different genes

Specific cell-cell contact serves as the developmental signal to deactivate discoidin I gene expression in Dictyostelium discoideum

Specific cell-cell contact is a major regulatory signal controlling cell differentiation in Dictyostelium discoideum, causing dramatic changes in the developmental program of gene expression. In this report, we focus on the relationships between specific cell-cell contact and the activity of the genes for discoidin I, an endogenous lectin that has been implicated in the cell-cell cohesion process. By performing quantitative RNA dot-hybridization assays and RNA gel blot-hybridization analyses, using as a probe a recombinant plasmid containing a discoidin I cDNA insert, we have measured changes in discoiding I mRNA levels during normal development and in response to specific manipulations of the state of cellular aggregation. Our major findings are as follows. (i) During normal development on filters, there is a close temporal correspondence between the establishment of specific cell-cell contacts and the decline in discoidin I mRNA levels. By the tight-aggregate stage, discoidin I mRNA is barely detectable. (ii) When tight aggregates are disaggregated and the cells are maintained in the disaggregated state, there is a dramatic rise in discoidin I mRNA content. (iii) When cells are developed in suspension (conditions that interfere with the establishment of tight cell-cell contacts), discoidin I mRNA accumulates to abnormally high levels, and these persist well after the levels in filter-developed cells have declined. Taken together, these results strongly suggest that cell-cell contact is the normal developmental signal to deactivate discoidin I gene expression; thus, a contact-deactivated gene for which a recombinant DNA probe is available has now been identified. Furthermore, we demonstrate that exogenous cAMP almost completely blocks the disaggregation-induced reactivation of discoidin I gene expression. Possible mechanistic relationships between specific cell-cell contact, intracellular cAMP levels, and developmental gene expression are discussed.

Discoidin I from Dictyostelium discoideum and Interactions with oligosaccharides: specificity, affinity, crystal structures, and comparison with discoidin II

Discoidin I (DiscI) and discoidin II (DiscII) are N-acetylgalactosamine (GalNAc)-binding proteins from Dictyostelium discoideum. They consist of two domains: an N-terminal discoidin domain and a C-terminal H-type lectin domain. They were cloned and expressed in high yield in recombinant form in Escherichia coli. Although both lectins bind galactose (Gal) and GalNAc, glycan array experiments performed on the recombinant proteins displayed strong differences in their specificity for oligosaccharides. DiscI and DiscII bind preferentially to Gal/GalNAcbeta1-3Gal/GalNAc-containing and Gal/GalNAcbeta1-4GlcNAcbeta1-6Gal/GalNAc-containing glycans, respectively. The affinity of the interaction of DiscI with monosaccharides and disaccharides was evaluated using isothermal titration calorimetry experiments. The three-dimensional structures of native DiscI and its complexes with GalNAc, GalNAcbeta1-3Gal, and Galbeta1-3GalNAc were solved by X-ray crystallography. DiscI forms trimers with involvement of calcium at the monomer interface. The N-terminal discoidin domain presents a structural similarity to F-type lectins such as the eel agglutinin, where an amphiphilic binding pocket suggests possible carbohydrate-binding activity. In the C-terminal H-type lectin domain, the GalNAc residue establishes specific hydrogen bonds that explain the observed affinity (K(d)=3x10(-4) M). The different specificities of DiscI and DiscII for oligosaccharides were rationalized from the different structures obtained by either X-ray crystallography or molecular modeling.

Discoidin proteins of Dictyostelium are necessary for normal cytoskeletal organization and cellular morphology during aggregation

The onset of aggregation of bacterially-grown Dictyostelium discoideum amoebae is accompanied by the accumulation of the discoidin proteins. An immunofluorescent analysis demonstrates that discoidin is distributed throughout the cytoplasm, but is excluded from vesicles and nucleoli. There is no indication of either extracellular or membrane localization. Translocating amoebae of mutants lacking discoidin form more dispersed pseudopodial regions at the cell periphery, possess an abnormally centered microtubule organizing center, are blunt rather than elongate, and lack the tapered posterior uropod characteristic of translocating wild-type cells. However, in spite of the loss of the normal elongate morphology, discoidinless mutants translocate with instantaneous velocities and directional persistence comparable to wild-type cells, and they respond normally to the rapid addition of cAMP. These results demonstrate that the discoidin proteins are cytoplasmic components essential for the maintenance of the elongate cell morphology, cytoskeletal organization and the ability to align with other cells during aggregation. However, the elongate morphology is not a requisite for rapid and persistent single cell translocation.

Translational control of discoidin lectin expression in drsA suppressor mutants of Dictyostelium discoideum

Genetic analysis in Dictyostelium discoideum has identified regulatory genes which control the developmental expression of the discoidin lectin multigene family. Among these, the drsA mutation is a dominant second-site suppressor of another mutation, disB, which has the discoidinless phenotype. We now demonstrate a novel mechanism by which the drsA allele exerts its suppressive effect on the disB mutation. Interestingly, drsA does not merely bypass the disB mutation and restore the wild-type pattern of lectin expression. Rather, drsA mutant cells have high levels of discoidin lectin synthesis during growth but do not express lectins during aggregation. In contrast, wild-type cells only express lectin protein during the aggregation period of development. Phenocopies of the drsA mutation show a pattern of discoidin expression similar to that seen in the bona fide mutant. These data suggest that there may be a mechanism of negative feedback, resulting from the high levels of discoidin lectin made during growth, which inhibits further discoidin lectin expression during development. Northern (RNA) analysis of developing drsA mutant cells shows that these cells contain high levels of discoidin mRNA, although no discoidin lectin protein is being translated from these messages. Therefore, expression of the discoidin gene family can be controlled at the level of translation as well as transcription.

Translational control of discoidin lectin expression in drsA suppressor mutants of Dictyostelium discoideum

Genetic analysis in Dictyostelium discoideum has identified regulatory genes which control the developmental expression of the discoidin lectin multigene family. Among these, the drsA mutation is a dominant second-site suppressor of another mutation, disB, which has the discoidinless phenotype. We now demonstrate a novel mechanism by which the drsA allele exerts its suppressive effect on the disB mutation. Interestingly, drsA does not merely bypass the disB mutation and restore the wild-type pattern of lectin expression. Rather, drsA mutant cells have high levels of discoidin lectin synthesis during growth but do not express lectins during aggregation. In contrast, wild-type cells only express lectin protein during the aggregation period of development. Phenocopies of the drsA mutation show a pattern of discoidin expression similar to that seen in the bona fide mutant. These data suggest that there may be a mechanism of negative feedback, resulting from the high levels of discoidin lectin made during growth, which inhibits further discoidin lectin expression during development. Northern (RNA) analysis of developing drsA mutant cells shows that these cells contain high levels of discoidin mRNA, although no discoidin lectin protein is being translated from these messages. Therefore, expression of the discoidin gene family can be controlled at the level of translation as well as transcription.

Biochemical and genetic characterization of a rapid-development strain in Dictyostelium discoideum

We have examined the rates of development of six wild-type and rapid-development strains of Dictyostelium discoideum. Strains NC4 and HU1231, a derivative of V12, have very similar developmental profiles. In comparison to these two strains, amoebae of the rapid-development strain HT100 reach the aggregation stage about 6 h earlier. Also, intracellular cAMP levels in HT100 increase precociously during early development. Postaggregative morphogenesis of HT100 proceeds at the same rate as NC4 and HU1231. In addition we have assessed the progress of development by RNA hybridization blotting. The appearance in HT100 of mRNAs associated with aggregation is advanced by 6 h while the appearance of early gene products is not affected appreciably. These data suggest that HT100 differs from strains NC4 and HU1231 primarily in the process of aggregation. We have partially characterized the genetic background of strain HT100. Mating and cell fusion analyses suggest that HT100 is a derivative of V12. We constructed a growth-temperature-sensitive derivative of HT100, and fused it with HU1231 cells. The resulting diploids develop at the same rate as HT100, suggesting that the rapid-development phenotype in HT100 is dominant.

Induction of gene expression in Dictyostelium by prestarvation factor, a factor secreted by growing cells

During growth, Dictyostelium cells continuously secrete a factor, PSF, that accumulates in proportion to cell density. At sufficient concentration, it triggers the production of discoidin I and certain lysosomal enzymes. Our earlier studies demonstrated these effects of PSF on protein and enzyme levels [Clarke et al., Differentiation 34:79-87, 1987; Clarke et al., Dev Genet 9: 315-326, 1988]. In the present study, we have examined whether PSF induces increased mRNA levels. By Northern blot analysis, we have found that discoidin I mRNA accumulates in exponentially growing NC4 cells as the cells reach high density; significant levels of mRNA are detectable in cells growing either on plates or in suspension, beginning about four generations before the end of exponential growth. High levels of discoidin I mRNA are also found in low-density cells grown in the presence of buffer conditioned by high-density cells. These results indicate that PSF induces the accumulation of discoidin I mRNA. Other "early developmental" genes, pCZ22 and the early I genes (16, 18, and 111), are also expressed in exponentially growing cells at high density or in the presence of conditioned buffer. We conclude that several genes previously found to be preferentially expressed very early in development are actually induced during late exponential growth by PSF.

Electrophoretic karyotype for Dictyostelium discoideum

This paper reports on the separation of the Dictyostelium discoideum chromosomes by pulse-field electrophoresis and the correlation of the electrophoretic pattern with linkage groups established by classical genetic methods. In two commonly used laboratory strains, five chromosome-sized DNA molecules have been identified. Although the majority of the molecular probes used in this study can be unambiguously assigned to established linkage groups, the electrophoretic karyotype differs between the closely related strains AX3k and NC4, suggesting that chromosomal fragmentation may have occurred during their maintenance and growth. The largest chromosome identified in this study is approximately 9 million base pairs. To achieve resolution with molecules of this size, programmed voltage gradients were used in addition to programmed pulse times.

The discoidin I gene family of Dictyostelium discoideum is linked to genes regulating its expression

The discoidin I protein has been studied extensively as a marker of early development in the cellular slime mold Dictyostelium discoideum. However, like most other developmentally regulated proteins in this system, no reliable information was available on the linkage of the discoidin genes to other known genes. Analysis of the linkage of the discoidin I genes by use of restriction fragment length polymorphisms revealed that all three discoidin I genes as well as a pseudogene are located on linkage group II. This evidence is consistent with the discoidin I genes forming a gene cluster that may be under the control of a single regulatory element. The discoidin I genes are linked to three genetic loci (disA, motA, daxA) that affect the expression of the discoidin I protein. Linkage of the gene family members to regulatory loci may be important in the coordinate maintenance of the gene family and regulatory loci. A duplication affecting the entire discoidin gene family is also linked to group II; this appears to be a small tandem duplication. This duplication was mapped using a DNA polymorphism generated by insertion of the Tdd-3 mobile genetic element into a Tdd-2 element flanking the gamma gene. A probe for Tdd-2 identified a restriction fragment length polymorphism in strain AX3K that was consistent with generation by a previously proposed Tdd-3 insertion event. A putative duplication or rearrangement of a second Tdd-2 element on linkage group IV of strain AX3K was also identified. This is the first linkage information available for mobile genetic elements in D. discoideum.

Multiple regulatory genes control expression of a gene family during development of Dictyostelium discoideum

Mutant strains of Dictyostelium discoideum carrying dis mutations fail to transcribe specifically the family of developmentally regulated discoidin lectin genes during morphogenesis. The phenotypes of these mutants strongly suggested that the mutations reside in regulatory genes. Using these mutant strains, we showed that multiple regulatory genes are required for the expression of the lectin structural genes and that these regulatory genes (the dis+ alleles) act in trans to regulate this gene family. These regulatory genes fall into two complementation groups (disA and disB) and map to linkage groups II and III, respectively. A further regulatory locus was defined by the identification of an unlinked supressor gene, drsA (discoidin restoring), which is epistatic to disB, but not disA, and results in the restoration of lectin expression in cells carrying the disB mutation. Mutant cells carrying the drsA allele express the discoidin lectin gene family during growth and development, in contrast to wild-type cells which express it only during development. Therefore, the suppressor activity of the drsA allele appears to function by making the expression of the discoidin lectins constitutive and no longer strictly developmentally regulated. The data indicate that normal expression of the discoidin lectins is dependent on the sequential action of the disB+, drsA+, and disA+ gene products. Thus, we described an interacting network of regulatory genes which in turn controls the developmental expression of a family of genes during the morphogenesis of D. discoideum.

Multiple regulatory genes control expression of a gene family during development of Dictyostelium discoideum

Mutant strains of Dictyostelium discoideum carrying dis mutations fail to transcribe specifically the family of developmentally regulated discoidin lectin genes during morphogenesis. The phenotypes of these mutants strongly suggested that the mutations reside in regulatory genes. Using these mutant strains, we showed that multiple regulatory genes are required for the expression of the lectin structural genes and that these regulatory genes (the dis+ alleles) act in trans to regulate this gene family. These regulatory genes fall into two complementation groups (disA and disB) and map to linkage groups II and III, respectively. A further regulatory locus was defined by the identification of an unlinked supressor gene, drsA (discoidin restoring), which is epistatic to disB, but not disA, and results in the restoration of lectin expression in cells carrying the disB mutation. Mutant cells carrying the drsA allele express the discoidin lectin gene family during growth and development, in contrast to wild-type cells which express it only during development. Therefore, the suppressor activity of the drsA allele appears to function by making the expression of the discoidin lectins constitutive and no longer strictly developmentally regulated. The data indicate that normal expression of the discoidin lectins is dependent on the sequential action of the disB+, drsA+, and disA+ gene products. Thus, we described an interacting network of regulatory genes which in turn controls the developmental expression of a family of genes during the morphogenesis of 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.

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.

Regulation of discoidin I gene expression in dictyostelium discoideum by cell-cell contact and cAMP

We have previously presented evidence that cell-cell contact is the normal developmental signal to deactivate discoidin I gene expression in D discoideum [Berger EA, Clark JM: Proc Natl Acad Sci USA 80:4983, 1983]. Here we provide genetic evidence to support this hypothesis by examining gene expression in a cohesion-defective mutant, strain EB-21, which enters the developmental program but is blocked at the loose mound stage. When this strain was developed in suspension, the cells remained almost entirely as single amoebae, unlike the wild type, which formed large multicellular aggregates. In both strains, discoidin I mRNA levels were low in vegetative cells but rose sharply during the first few hours of development. However, the peak level reached at 8 hr in EB-21 exceeded that observed in wild type, and while the level declined markedly over the next few hours in wild type, it remained highly elevated in the mutant. Thus, there was a correlation between the inability of EB-21 to form normal cell-cell contacts and its deficiency in inactivating discoidin I gene expression. Previous studies from several laboratories, including this one, have demonstrated that exogenously added cAMP can block or reverse the changes in gene expression normally seen upon cell disaggregation. This has led us to propose that cAMP serves as a second messenger regulating the expression of contact-regulated genes. Here we provide additional support for this hypothesis. Intracellular cAMP levels rapidly dropped several-fold when wild type tight cell aggregates were disaggregated and remained low as the cells were cultured in the disaggregated state. Furthermore, overexpression of discoidin I mRNA late in development in EB-21 was corrected by addition of high concentrations of cAMP. These results are consistent with a second messenger function for cAMP in the contact-mediated regulatory response, and they indicate that the cAMP response machinery for discoidin I gene expression is capable of functioning in the cohesion-defective EB-21 strain.

Overproduction of discoidin I by a temperature-sensitive motility mutant of Dictyostelium discoideum

Dictyostelium discoideum MC2 is a temperature-sensitive motility mutant of AX3. Mutant cells are incapable of growth, phagocytosis, and migration under restrictive conditions (Kayman et al., J. Cell Biol. 92:705-711, 1982). We show here that at the restrictive temperature MC2 cells grown axenically or on bacteria synthesized excessive quantities of the lectin discoidin I. By two-dimensional gel electrophoresis and peptide mapping, the proteins overproduced by MC2 cells were indistinguishable from discoidin I synthesized at lower levels in AX3 cells. At least two of the three species of discoidin I were overproduced. This protein family constituted 9% of the total protein in cells that were incubated overnight at 27 degrees C in axenic medium. Although MC2 cells are defective in nutrient uptake under restrictive conditions, the overproduction of discoidin I did not appear to be part of a pleiotropic response to starvation. We propose that transcription of the coordinately regulated discoidin I genes is altered in mutant cells. This alteration may be related to the motility defects manifested by MC2.

Overproduction of discoidin I by a temperature-sensitive motility mutant of Dictyostelium discoideum

Dictyostelium discoideum MC2 is a temperature-sensitive motility mutant of AX3. Mutant cells are incapable of growth, phagocytosis, and migration under restrictive conditions (Kayman et al., J. Cell Biol. 92:705-711, 1982). We show here that at the restrictive temperature MC2 cells grown axenically or on bacteria synthesized excessive quantities of the lectin discoidin I. By two-dimensional gel electrophoresis and peptide mapping, the proteins overproduced by MC2 cells were indistinguishable from discoidin I synthesized at lower levels in AX3 cells. At least two of the three species of discoidin I were overproduced. This protein family constituted 9% of the total protein in cells that were incubated overnight at 27 degrees C in axenic medium. Although MC2 cells are defective in nutrient uptake under restrictive conditions, the overproduction of discoidin I did not appear to be part of a pleiotropic response to starvation. We propose that transcription of the coordinately regulated discoidin I genes is altered in mutant cells. This alteration may be related to the motility defects manifested by MC2.

Two nuclear DNA binding proteins of Dictyostelium discoideum with a high affinity for poly(dA)-poly(dT)

Intergenic regions of the Dictyostelium genome contain an extremely high proportion of AT base pairs. Those intergenic regions which have been subjected to nucleotide sequence analysis are predominantly composed of alternating runs of poly(dA) and poly(dT) and there is evidence to suggest that nucleosomes do not form on such sequences. We have identified two nuclear proteins, of molecular weight 70,000 and 74,000 daltons, which bind only to intergenic regions of a cloned Dictyostelium gene. Binding is specifically inhibited in the presence of synthetic poly(dA) - poly (dT) as competitor. These proteins may play some role in the chromosomal organization of intergenic regions in Dictyostelium discoideum.

Mutants of Dictyostelium discoideum blocked in expression of all members of the developmentally regulated discoidin multigene family

Mutant strains of D. discoideum are described that can complete morphogenesis and cytodifferentiation but which express vastly reduced levels of the galactose-binding lectins discoidin I and II (less than 1% and 1%-2% respectively) compared to the wild-type control. Mutant cells proceeding through development lack lectin activity, lectin protein, and specific lectin mRNA. In contrast, the genes encoding these proteins are present in their wild-type configurations in the genome. Since these proteins are encoded by four to five discrete genes, the mutations in these strains are most likely in genes involved in the regulation of the expression of members of this multigene family. The results also indicate that the discoidin lectins may not be required for fruiting body construction in this organism. Finally, coupled with the recent ability to transform D. discoideum, these mutants open the way to identification and isolation of regulatory genes and their products.

Ion dependence of the discoidin I lectin from Dictyostelium discoideum

The lectin discoidin I from Dictyostelium discoideum requires divalent cations for binding activity. The data indicate that calcium is the preferred ion in vitro. In contrast, the lectin activity of discoidin II is independent of divalent ions.

Regulation of dictyostelium discoideum mRNAs specific for prespore or prestalk cells

Prespore and prestalk cells in Dictyostelium discoideum aggregates can be separated by density gradient centrifugation. Using poly(A+) RNA from the fractionated cells to probe a cDNA library of mRNAs from postaggregation cells, we were able to identify six cDNA clones representing RNAs enriched in prespore or prestalk cells. Remarkably, transcripts of six of seven cDNA clones, previously selected to encode mRNAs present in postaggregating cells but low or absent in growing cells, also are enriched in RNA from either prestalk or prespore cells. By hybridization of cDNA probes to nitrocellulose blots of formaldehyde RNA gels, these 13 mRNA species have been examined with respect to cell type specificity, temporal pattern of accumulation, and affect of disaggregation and cAMP on accumulation. Aggregation-stage mRNAs tend to fit into three different classes. All prespore mRNAs are similar in all aspects of their regulation, while prestalk mRNAs fall into two co-regulated classes. All mRNAs that are present at significant levels during growth and differentiation are found in both cell types at comparable levels. Our results indicate that there is coordinate control of expression of genes specific for the two principal cell types.

A temperature-dependent choice in cell differentiation

Ascension of the cell mass during culmination was observed to be temperature-sensitive in strain HH31 of the cellular slime mold Dictyostelium discoideum. A sequence of additional developmental abnormalities was also observed both preceeding and succeeding culmination. Slugs reared at the restrictive temperature (27 degrees C), in contrast to those reared at the permissive temperature (22 degrees C), were deficient in the expression of six prespore markers and elevated in the production of four prestalk markers. Following attempted culmination at the restrictive temperature, the majority of cells were stalk cells according to fluorescence, phase contrast, electron microscopic, biochemical, and plating efficiency criteria. These findings were correlated with a general diminution of staining of slug cell Membrane extracts on polyacrylamide gels with FITC-wheat germ agglutinin. The effect of the higher temperature was readily reversible prior to terminal differentiation. An interdependence of several of the changes was suggested by the observation that in two derivative strains the temperature-dependence of these changes was coordinately altered. In summary, a large fraction of the slug cells of HH31 appear to be temperature-dependent in their choice of pathways of cell differentiation, this change is related to a modification of the cell surface, and the choice made in the slug is remembered by cells as they terminally differentiate.

Cell-surface discoidin in aggregating cells of Dictyostelium discoideum

Both discoidin I and discoidin II have been detected on the surface of aggregating (10 h developmental stage) cells of Dictyostelium discoideum NC4 by radioiodination of the cell-surface followed by immunoprecipitation and sodium dodecyl sulphate/polyacrylamide-gel-electrophoretic analysis. Approx. 92% of cell-surface discoidin I and 72% of cell-surface discoidin II can be eluted with 0.5 M-galactose, showing that most of each endogenous lectin is not present as integral membrane protein but rather is bound to cell-surface discoidin receptors. Two-dimensional polyacrylamide-gel-electrophoretic analysis of discoidin I suggests that the native tetramer may be a hetero-multimer composed of both Ia and Ib subunits. Cell-surface discoidin I also contains both types of subunit, but it is not clear whether both subunits have corresponding cell-surface receptors.

Discoidins I and II: common and unique regions on two lectins implicated in cell--cell cohesion in Dictyostelium discoideum

As Dictyostelium discoideum amoebae differentiate from the noncohesive to the mutually cohesive state, they synthesize two galactose-binding lectins--discoidins I and II--which have been implicated as obligatory components of the morphogenetic cell-cell recognition and cohesion system. These proteins have been shown to have similar amino acid compositions and subunit Mr and overlapping but distinct carbohydrate recognition specificities. We have performed extensive immunochemical and biochemical analyses to study the structural relationships between these two molecules and to eventually identify structural and functional domains. Antisera raised against highly purified preparations of discoidin I and discoidin II were tested for their reactivities against each protein by both immunoprecipitation and double diffusion analyses. The patterns of crossreactivity indicated the presence of shared as well as unique antigenic determinants. This interpretation was supported by two-dimensional thin-layer peptide map analysis and by studies with purified peptides. Of approximately 10-12 peptides observed after exhaustive tryptic digestion of each radioiodinated lectin, 3 appeared to be common to both. These putative common peptides were purified, and the corresponding peptides from discoidins I and II were found to behave identically by two-dimensional thin-layer analysis, gel filtration, and susceptibility to chymotrypsin. The finding of common and unique regions in discoidins I and II suggests analogies with other families of recognition proteins and may have important functional implications for these cell-cell recognition molecules.

Differential expression of the members of the discoidin I multigene family during growth and development of Dictyostelium discoideum

Discoidin I and II are lectins synthesized during the aggregation of Dictyostelium discoideum amoebae which may play a role in cellular cohesion. Discoidin I was thought to consist of two major polypeptides, but we show that there are three. The N-terminal amino acid sequence of the polypeptides has been predicted by determining part of the nucleotide sequence of their respective mRNAs. We obtained the nucleotide sequences by reverse transcription of the mRNAs, using as primers, fragments derived from the coding region of two cloned discoidin I sequences, and utilizing cross hybridization to the various mRNA species and differences in the length of their 5' noncoding regions to isolate fragments for DNA sequencing. We used primer extension to measure the relative concentration of the three major discoidin I mRNA sequences. We show that during development changes in the abundance of all three mRNA sequences occur coordinately. In cells growing in nutrient broth, however, only two of the three major discoidin I mRNA sequences accumulate, and if such cells are grown to a very high density, both sequences disappear. These results indicate that the coordination of discoidin I gene expression is not obligatory and that the members of this multigene family may differ in the mode of their induction during normal development.

Characterization of sequence elements at the 5' end of a discoidin I gene isolated from Dictyostelium discoideum

The discoidin I genes of Dictyostelium discoideum encode a family of three closely related developmentally regulated lectins which may play a role in cell cohesion. We have isolated a genomic clone containing the 5' half of a discoidin I gene with 12kb of flanking sequence and we have identified the discoidin I polypeptide encoded by this gene. We have determined part of the nucleotide sequence of the cloned segment and have hence determined the N-terminal amino acid sequence of the encoded polypeptide. The nucleotide sequence upstream of the AUG initiation codon was unusually AT rich, with 94% AT base pairs in the 171 nucleotides for which sequence was determined. However, having determined the start point of transcription ('cap' site) two striking features of similarity with other eukaryotic structural genes became apparent. The sequence TATAAA was present 33 nucleotides upstream from the 'cap' site and the sequence CCAAT was present a further 20 nucleotides upstream.