Transient expression of a mitochondrial gene cluster including rps4 is essential for the phase-shift of Dictyostelium cells from growth to differentiation

Using synchronized Dictyostelium discoideum Ax-2 cells and the differential display method, a mitochondrial gene cluster (referred to as differentiation-associated gene 3; dia3) was isolated as one of the genes expressed specifically during the transition of Ax-2 cells from growth to differentiation. The dia3 gene encodes for a mitochondrial protein cluster (NADH dehydrogenase (NAD) subunit 11, 5, ribosomal protein S4 (RPS4), RPS2, and NAD4L). Northern blot analysis using nonsynchronized Ax-2 cells has shown that the dia3 RNA of about 8 kb is scarcely expressed during the vegetative growth phase, and the maximal expression was attained at 2 h after starvation. To analyze the gene function of dia3, we tried inactivation of rps4 by means of homologous recombination and obtained several transformed clones showing mitochondrial DNA heteroplasmy. The transformed cells grew normally in nutrient medium, but their development after starvation was greatly impaired, thus resulting in the failure of many cells to differentiate. In this connection, the cAMP receptor 1 (car1) expression, which is one of the earliest markers of differentiation, was found to be markedly reduced in the rps4-inactivated cells.     

Involvement of the glucose-regulated protein 94 (Dd-GRP94) in starvation response of Dictyostelium discoideum cells

Upon deprivation of nutrients, Dictyostelium discoideum Ax-2 cells arrest proliferation and initiate a metamorphosed developmental program including induction of altered gene expressions which are necessary for differentiation. In Ax-2 cells, we found out a member of Hsp90 family usually contained in the endoplasmic reticulum (ER), Dd-GRP94 (Dictyostelium discoideum glucose-regulated protein 94). In general, GRP94 are induced either by glucose-depletion or by depletion of Ca(2+) in intracellular Ca(2+) stores. Unexpectedly, however, the expression of Dd-grp94 was greatly reduced within 60 min of starvation. Dd-grp94-overexpressing cells (GRP94(OE) cells) collected without forming distinct aggregation streams, and never formed normal fruiting bodies. Also, prespore differentiation as well as maturation into spores and stalk cells were particularly impaired in the GRP94(OE) cells. Thus Dd-GRP94 seems to be crucial in late differentiation as well as in starvation response.     

Transient expression of a mitochondrial gene cluster including rps4 is essential for the phase‐shift of Dictyostelium cells from growth to differentiation

Using synchronized Dictyostelium discoideum Ax‐2 cells and the differential display method, a mitochondrial gene cluster (referred to as differentiation‐associated gene 3; dia3) was isolated as one of the genes expressed specifically during the transition of Ax‐2 cells from growth to differentiation. The dia3 gene encodes for a mitochondrial protein cluster (NADH dehydrogenase (NAD) subunit 11, 5, ribosomal protein S4 (RPS4), RPS2, and NAD4L). Northern blot analysis using nonsynchronized Ax‐2 cells has shown that the dia3 RNA of about 8 kb is scarcely expressed during the vegetative growth phase, and the maximal expression was attained at 2 h after starvation. To analyze the gene function of dia3, we tried inactivation of rps4 by means of homologous recombination and obtained several transformed clones showing mitochondrial DNA heteroplasmy. The transformed cells grew normally in nutrient medium, but their development after starvation was greatly impaired, thus resulting in the failure of many cells to differentiate. In this connection, the cAMP receptor 1 (car1) expression, which is one of the earliest markers of differentiation, was found to be markedly reduced in the rps4‐inactivated cells. Dev. Genet. 25:339–352, 1999. © 1999 Wiley‐Liss, Inc.     

蕨类植物叶绿体rps4基因的适应性进化分析

在原核生物和植物叶绿体中,RPS4(ribosomal protein small subunit4)在核糖体30S小亚基形成起始过程中发挥重要作用;该蛋白在植物中由叶绿体rps4基因编码。为验证蕨类植物在白垩纪适应被子植物兴起而发生分化的观点,本文以23种蕨类植物为研究对象,利用分支模型、位点模型和分支位点模型对其叶绿体rps4基因进化适应性进行分析。分支模型检测到4个可能存在正选择的分支;位点模型和分支位点模型虽然没有检测出正选择位点,但是位点模型检测出了85个负选择位点。通过研究我们仅仅得出a、b两个代表水龙骨类的分支处于正选择压力下,这与水龙骨类在白垩纪发生辐射式演化的理论相一致。同时rps4基因处于强烈的负选择压力这一事实表明该基因的功能与结构已经趋于稳定。     

Novel functions of ribosomal protein S6 in growth and differentiation of Dictyostelium cells

We have previously shown that in Dictyostelium cells a 32 kDa protein is rapidly and completely dephosphorylated in response to starvation that is essential for the initiation of differentiation (Akiyama & Maeda 1992). In the present work, this phosphoprotein was identified as a homologue (Dd-RPS6) of ribosomal protein S6 (RPS6) that is an essential member for protein synthesis. As expected, Dd-RPS6 seems to be absolutely required for cell survival, because we failed to obtain antisense-RNA mediated cells as well as Dd-rps6-null cells by homologous recombination in spite of many trials. In many kinds of cell lines, RPS6 is known to be located in the nucleus and cytosol, but Dd-RPS6 is predominantly located in the cell cortex with cytoskeletons, and in the contractile ring of just-dividing cells. In this connection, the overexpression of Dd-RPS6 greatly impairs cytokinesis during axenic shake-cultures in growth medium, resulting in the formation of multinucleate cells. Much severe impairment of cytokinesis was observed when Dd-RPS6-overexpressing cells (Dd-RPS6(OE) cells) were incubated on a living Escherichia coli lawn. The initiation of differentiation triggered by starvation was also delayed in Dd-RPS6(OE) cells. In addition, Dd-RPS6(OE) cells exhibit defective differentiation into prespore cells and spores during late development. Thus, it is likely that the proper expression of Dd-RPS6 may be of importance for the normal progression of late differentiation as well as for the initiation of differentiation.     

Plant mitochondrial rps2 genes code for proteins with a C-terminal extension that is processed

A gene (rps2) coding for ribosomal protein S2 (RPS2) is present in the mitochondrial (mt) genome of several monocot plants, but absent from the mtDNA of dicots. Confirming that in dicot plants the corresponding gene has been transferred to the nucleus, a corresponding Arabidopsis thaliana nuclear gene was identified that codes for mitochondrial RPS2. As several yeast and mammalian genes coding for mt ribosomal proteins, the Arabidopsis RPS2 apparently has no N-terminal targeting sequence. In the maize mt genome, two rps2 genes were identified and both are transcribed, although at different levels. As in wheat and rice, the maize genes code for proteins with long C-terminal extensions, as compared to their bacterial counterparts. These extensions are not conserved in sequence. Using specific antibodies against one of the maize proteins we found that a large protein precursor is indeed synthesized, but it is apparently processed to give the mature RPS2 protein which is associated with the mitochondrial ribosome.     

RRS1 and RPS4 provide a dual Resistance-gene system against fungal and bacterial pathogens

Colletotrichum higginsianum is a fungal pathogen that infects a wide variety of cruciferous plants, causing important crop losses. We have used map-based cloning and natural variation analysis of 19 Arabidopsis ecotypes to identify a dominant resistance locus against C. higginsianum . This locus named RCH2 (for recognition of C. higginsianum ) maps in an extensive cluster of disease-resistance loci known as MRC-J in the Arabidopsis ecotype Ws-0. By analyzing natural variations within the MRC-J region, we found that alleles of RRS1 ( resistance to Ralstonia solanacearum 1 ) from susceptible ecotypes contain single nucleotide polymorphisms that may affect the encoded protein. Consistent with this finding, two susceptible mutants, rrs1-1 and rrs1-2 , were identified by screening a T-DNA-tagged mutant library for the loss of resistance to C. higginsianum . The screening identified an additional susceptible mutant ( rps4-21 ) that has a 5-bp deletion in the neighboring gene, RPS4-Ws , which is a well-characterized R gene that provides resistance to Pseudomonas syringae pv. tomato strain DC3000 expressing avrRps4 ( Pst - avrRps4 ). The rps4-21 / rrs1-1 double mutant exhibited similar levels of susceptibility to C. higginsianum as the single mutants. We also found that both RRS1 and RPS4 are required for resistance to R. solanacearum and Pst-avrRps4 . Thus, RPS4-Ws and RRS1-Ws function as a dual resistance gene system that prevents infection by three distinct pathogens.     

The two Arabidopsis RPS6 genes, encoding for cytoplasmic ribosomal proteins S6, are functionally equivalent

Many eukaryotic genomes have experienced ancient whole-genome duplication (WGD) followed by massive gene loss. These eliminations were not random since some gene families were preferentially retained as duplicates. The gene balance hypothesis suggests that those genes with dosage reduction can imbalance their interacting partners or complex, resulting in decreased fitness. In Arabidopsis, the cytoplasmic ribosomal proteins (RP) are encoded by gene families with at least two members. We have focused our study on the two RPS6 genes in an attempt to understand why they have been retained as duplicates. We demonstrate that RPS6 function is vital for the plant. We also show that reducing the level of RPS6 accumulation (in the knock-out rps6a or rps6b single mutants, or in the double heterozygous RPS6A/rps6a,RPS6B/rps6b), confers a slow growth phenotype (haplodeficiency). Importantly, we demonstrate that the functions of two RPS6 genes are redundant and interchangeable. Finally, like in most other described Arabidopsis rp mutants, we observed that a reduced RPS6 level slightly alters the dorsoventral leaf patterning. Our results support the idea that the Arabidopsis RPS6 gene duplicates were evolutionarily retained in order to maintain an expression level necessary to sustain the translational demand of the cell, in agreement with the gene balance hypothesis.     

A gene coding for an RPS2 protein is present in the mitochondrial genome of several cereals, but not in dicotyledons

A gene coding for a protein that shows homologies to prokaryotic ribosomal protein S2 is present in the mitochondrial (mt) genome of wheat (Triticum aestivum). The wheat gene is transcribed as a single mRNA which is edited by C-to-U conversions at seven positions, all resulting in alteration of the encoded amino acid. Homologous gene sequences are also present in the mt genomes of rice and maize, but we failed to identify the corresponding sequences in the mtDNA of all dicotyledonous species tested; in these species the mitochondrial RPS2 is probably encoded in the nucleus. The protein sequence deduced from the wheat rps2 gene sequence has a long C-terminal extension when compared to other prokaryotic RPS2 sequences. This extension presents no similarity with any known sequence and is not conserved in the maize or rice mitochondrial rps2 gene. Most probably, after translation, this peptide extension is processed by a specific peptidase to give rise to the mature wheat mitochondrial RPS2.     

Initiation of RPS2-specified disease resistance in Arabidopsis is coupled to the AvrRpt2-directed elimination of RIN4

Plants have evolved a sophisticated innate immune system to recognize invading pathogens and to induce a set of host defense mechanisms resulting in disease resistance. Pathogen recognition is often mediated by plant disease resistance (R) proteins that respond specifically to one or a few pathogen-derived molecules. This specificity has led to suggestions of a receptor-ligand mode of R protein function. Delivery of the bacterial effector protein AvrRpt2 by Pseudomonas syringae specifically induces disease resistance in Arabidopsis plants expressing the RPS2 R protein. We demonstrate that RPS2 physically interacts with Arabidopsis RIN4 and that AvrRpt2 causes the elimination of RIN4 during activation of the RPS2 pathway. AvrRpt2-mediated RIN4 elimination also occurs in the rps2, ndr1, and Atrar1 mutant backgrounds, demonstrating that this activity can be achieved independent of an RPS2-mediated signaling pathway. Therefore, we suggest that RPS2 initiates signaling based upon perception of RIN4 disappearance rather than direct recognition of AvrRpt2.     

Molecular adaptation and expression evolution following duplication of genes for organellar ribosomal protein S13 in rosids

Background  

Gene duplication has been a fundamental process in the evolution of eukaryotic genomes. After duplication one copy (or both) can undergo divergence in sequence, expression pattern, and function. Two divergent copies of the ribosomal protein S13 gene (rps13) of chloroplast origin are found in the nucleus of the rosids Arabidopsis, Gossypium, and Glycine. One encodes chloroplast-imported RPS13 (nucp rps13), while the other encodes mitochondria-imported RPS13 (numit rps13). The rps13 gene has been lost from mitochondrial DNA (mt rps13) of many rosids.     

A gene coding for an RPS2 protein is present in the mitochondrial genome of several cereals, but not in dicotyledons

A gene coding for a protein that shows homologies to prokaryotic ribosomal protein S2 is present in the mitochondrial (mt) genome of wheat (Triticum aestivum). The wheat gene is transcribed as a single mRNA which is edited by C-to-U conversions at seven positions, all resulting in alteration of the encoded amino acid. Homologous gene sequences are also present in the mt genomes of rice and maize, but we failed to identify the corresponding sequences in the mtDNA of all dicotyledonous species tested; in these species the mitochondrial RPS2 is probably encoded in the nucleus. The protein sequence deduced from the wheat rps2 gene sequence has a long C-terminal extension when compared to other prokaryotic RPS2 sequences. This extension presents no similarity with any known sequence and is not conserved in the maize or rice mitochondrial rps2 gene. Most probably, after translation, this peptide extension is processed by a specific peptidase to give rise to the mature wheat mitochondrial RPS2. Received: 20 November 1997 / Accepted: 29 January 1998     

Coaggregation-mediated interactions of streptococci and actinomyces detected in initial human dental plaque

Streptococci and actinomyces that initiate colonization of the tooth surface frequently coaggregate with each other as well as with other oral bacteria. These observations have led to the hypothesis that interbacterial adhesion influences spatiotemporal development of plaque. To assess the role of such interactions in oral biofilm formation in vivo, antibodies directed against bacterial surface components that mediate coaggregation interactions were used as direct immunofluorescent probes in conjunction with laser confocal microscopy to determine the distribution and spatial arrangement of bacteria within intact human plaque formed on retrievable enamel chips. In intrageneric coaggregation, streptococci such as Streptococcus gordonii DL1 recognize receptor polysaccharides (RPS) borne on other streptococci such as Streptococcus oralis 34. To define potentially interactive subsets of streptococci in the developing plaque, an antibody against RPS (anti-RPS) was used together with an antibody against S. gordonii DL1 (anti-DL1). These antibodies reacted primarily with single cells in 4-h-old plaque and with mixed-species microcolonies in 8-h-old plaque. Anti-RPS-reactive bacteria frequently formed microcolonies with anti-DL1-reactive bacteria and with other bacteria distinguished by general nucleic acid stains. In intergeneric coaggregation between streptococci and actinomyces, type 2 fimbriae of actinomyces recognize RPS on the streptococci. Cells reactive with antibody against type 2 fimbriae of Actinomyces naeslundii T14V (anti-type-2) were much less frequent than either subset of streptococci. However, bacteria reactive with anti-type-2 were seen in intimate association with anti-RPS-reactive cells. These results are the first direct demonstration of coaggregation-mediated interactions during initial plaque accumulation in vivo. Further, these results demonstrate the spatiotemporal development and prevalence of mixed-species communities in early dental plaque.     

Specific expression of a gene encoding a novel calcium-binding protein, CAF-1, during transition of Dictyostelium cells from growth to differentiation

The gene expressions involved in the transition from cell proliferation to differentiation were analyzed, using synchronized Dictyostelium discoideum Ax-2 cells and the differential plaque hybridization method. As one of the genes (cDNA) specifically expressed when Ax-2 cells were starved just before the putative shift (PS)-point (putative shift point; a switchover point from growth to differentiation in the cell cycle), calfumirin-1 ( CAF-1 ) was cloned, which encoded a novel calcium-binding protein with E-F hand. Although CAF-1 mRNA was slightly expressed in vegetatively growing cells, the expression was markedly increased in response to starvation of cells just before the PS-point. Northern analysis using non-synchronized Ax-2 cells showed that the CAF-1 mRNA is predominantly expressed within a few hours of starvation. Such a starvation-induced early expression of the CAF-1 mRNA raised a possibility that CAF-1 might be one of Ca²⁺-binding proteins involved in the phase-shift of cells from growth to differentiation.