Isolation and characterization of an Arabidopsis thaliana gene for the 54 kDa subunit of the signal recognition particle

Loquat (Eriobotrya japonica (Thunb.) Lindl) population genomics suggests a two-staged domestication and identifies genes showing convergence/parallel selective sweeps with apple or peach

Crop domestication and evolution represent key fields of plant and genetics research. Here, we re-sequenced and analyzed whole genome data from 51 wild accessions and 53 representative cultivars of Eriobotrya japonica, an important semi-subtropical fruit crop. Population genomics analysis suggested that modern cultivated E. japonica experienced a two-staged domestication fitting the "marginality model," being initially domesticated in west-northern Hubei province from a mono-phylogenetic wild progenitor, then refined mainly in Jiangsu, Zhejiang and Fujian provinces of China. Cultivated E. japonica has experienced little reduction in genome-wide nucleotide polymorphism compared with wild forms. Genes responsible for sugar biosynthesis were enriched in regions harboring putative selective sweeps. An approach based on co-clustering into gene families and evaluating chromosome colinearity of orthologous and paralogous genes was used to identify convergent/parallel selective sweeps among different crops. Specifically, more than one hundred of orthologs and paralogs undergoing selective sweeps were identified between loquat, apple and peach, among which 14 encoded "UDP glycosyltransferase 1." In sum, the study not only provided valuable information for breeding of E. japonica, but also enriched knowledge of crop domestication.

The dynamics of plant plasma membrane proteins: PINs and beyond

Plants are permanently situated in a fixed location and thus are well adapted to sense and respond to environmental stimuli and developmental cues. At the cellular level, several of these responses require delicate adjustments that affect the activity and steady-state levels of plasma membrane proteins. These adjustments involve both vesicular transport to the plasma membrane and protein internalization via endocytic sorting. A substantial part of our current knowledge of plant plasma membrane protein sorting is based on studies of PIN-FORMED (PIN) auxin transport proteins, which are found at distinct plasma membrane domains and have been implicated in directional efflux of the plant hormone auxin. Here, we discuss the mechanisms involved in establishing such polar protein distributions, focusing on PINs and other key plant plasma membrane proteins, and we highlight the pathways that allow for dynamic adjustments in protein distribution and turnover, which together constitute a versatile framework that underlies the remarkable capabilities of plants to adjust growth and development in their ever-changing environment.

Functional divergence of the plastid and cytosolic forms of the 54-kDa subunit of signal recognition particle

Chloroplast and cytoplasmic signal recognition particles (cpSRP and cySRP) each contain a similar subunit, SRP54. The chloroplast homologue binds to cpSRP43, which is absent from cytosolic SRP, and cySRP54 binds to SRP-RNA, which appears to be absent from cpSRP. In the presence of cpSRP43, cpSRP54 posttranslationally forms a soluble targeting intermediate, transit complex, with the major light harvesting protein of the thylakoid membrane. In contrast, cySRP54 functions cotranslationally. In this study we investigated whether cytosolic and chloroplast forms of SRP54 were interchangeable in three types of functional assays: complementation of an Escherichia coli SRP54 mutant, formation of the transit complex, and heterologous binding between the SRP54 subunits, cpSRP43, and SRP-RNA. In no cases were the 54-kDa subunits able to substitute for each other suggesting that the two proteins are fundamentally different.

Cloning, yeast expression, and characterization of the coupling of two distantly related Arabidopsis thaliana NADPH-cytochrome P450 reductases with P450 CYP73A5

Two NADPH-cytochrome P450 reductase-encoding cDNAs were isolated from an Arabidopsis cDNA library by metabolic interference in a Saccharomyces cerevisiae mutant disrupted for its endogenous cpr1 gene. ATR1 encodes a protein of 692 amino acids, while ATR2 encodes either a 712-residue protein (ATR2-1), or a 702-residue protein (ATR2-2) depending on the choice of the initiation codon. Comparative analysis of ATR1 and ATR2-1 indicates 64% amino acid sequence identity and the absence of conservation in the third base of conserved amino acid codons. The two Arabidopsis reductases are encoded by distinct genes whose divergence is expected an early event in angiosperms evolution. A poly(Ser/Thr) stretch reminiscent of a plant chloroplastic targeting signal is present at the ATR2-1 N-terminal end but absent in ATR1. The cDNA open reading frames were expressed in yeast. The recombinant polypeptides were found present in the yeast endoplasmic reticulum membrane and exhibited a high specific NADPH-cytochrome c reductase activity. To gain more insight into the respective functions of the two reductases, the Arabidopsis cDNA encoding cinnamate 4-hydroxylase (CYP73A5) was cloned and co-expressed with ATR1 or ATR2 in yeast. Biochemical characterization of the Arabidopsis ATR1/CYP73A5 and ATR2-1/CYP73A5 systems demonstrates that the two distantly related Arabidopsis reductases similarly support the first oxidative step of the phenylpropanoid general pathway.

Heat shock inhibits release of the signal recognition particle from the endoplasmic reticulum in barley aleurone layers

When barley (Hordeum vulgare) aleurone layers are subjected to heat shock there is a selective degradation of the normally stable mRNAs encoding secreted proteins. Messages for nonsecreted proteins are not degraded. The synthesis of heat shock proteins is not required for this selective message degradation. Our hypothesis explaining this phenomenon is that a component of the early steps in the synthesis of secreted proteins is damaged by heat shock, resulting in a selective halt in translation on secretory mRNAs, which may in turn lead to degradation of those messages. The first committed step in the synthesis of secreted proteins is the binding of the nascent signal sequence to the signal recognition particle. We have obtained cDNA clones and antibodies for the barley 54-kDa subunit of the signal recognition particle. In cell fractionation experiments, more signal recognition particle was bound to the endoplasmic reticulum membranes and less was in the free particle fraction following a heat shock. The results suggest that heat shock inhibits the release of the signal recognition particle from the endoplasmic reticulum. This would, in turn, inhibit the resumption of translation and may be the underlying cause of the secretory message degradation.

Transport of proteins in eukaryotic cells: more questions ahead

Some newly synthesized proteins contain signals that direct their transport to their final location within or outside of the cell. Targeting signals are recognized by specific protein receptors located either in the cytoplasm or in the membrane of the target organelle. Specific membrane protein complexes are involved in insertion and translocation of polypeptides across the membranes. Often, additional targeting signals are required for a polypeptide to be further transported to its site of function. In this review, we will describe the trafficking of proteins to various cellular organelles (nucleus, chloroplasts, mitochondria, peroxisomes) with emphasis on transport to and through the secretory pathway.

Identification of a region of Bacillus subtilis Ffh, a homologue of mammalian SRP54 protein, that is essential for binding to small cytoplasmic RNA

Bacillus subtilis Ffh and scRNA are homologues of mammalian SRP54 and SRP RNA, respectively, which are components of the eukaryotic signal recognition particle (SRP). Ffh (446 amino acids) interacts with scRNA to form a stable complex in vivo. Here, we identified an RNA-binding domain of Ffh. The results obtained using a series of deletion mutants show that amino acid positions 364 to 432 in the C-terminal region of Ffh correlates with its ability to bind RNA. The amino acid sequence of this region is well conserved among members of the SRP54 protein family. This sequence contains two hydrophobic regions (h2, 364 to 391, and h3, 416 to 435), separated by the positively charged amino acid motif, 398RRKRIAKGSG407. Among the basic amino acid residues in this region, Arg-401 was essential for binding to scRNA, but Arg-399 and Lys-400 were not. The co-existence of Arg-398 and Lys-404 was necessary for the same affinity as wild type Ffh. The two glycine residues of the 405GSG407 were also essential. MH23 peptide (91 amino acids) encompassing from 356 to 446, consisting of h2-RRKRIAKGSG-h3, bound scRNA with the same affinity as wild type Ffh, whereas a 24-amino acid synthetic peptide 392DIINASRRKRIAKGSGTSVQEVNR415 did not. The region containing two hydrophobic segments separated by the positively charged motif is the minimal requirement of Ffh for RNA binding.

Signal recognition particle (SRP), a ubiquitous initiator of protein translocation

In higher eukaryotes, most secretory and membrane proteins are synthesised by ribosomes which are attached to the membrane of the rough endoplasmic reticulum (RER). This allows the proteins to be translocated across that membrane already during their synthesis. The ribosomes are directed to the RER membrane by a cytoplasmic ribonucleoprotein particle, the signal recognition particle (SRP). SRP fulfills its task by virtue of three distinguishable activities: the binding of a signal sequence which, being part of the nascent polypeptide to be translocated, is exposed on the surface of a translating ribosome; the retardation of any further elongation; and the SRP-receptor-mediated binding of the complex of ribosome, nascent polypeptide and SRP to the RER membrane which results in the detachment of SRP from the signal sequence and the ribosome and the insertion of the nascent polypeptide into the membrane. Evidence is accumulating that SRP is not restricted to eukaryotes: SRP-related particles and SRP-receptor-related molecules are found ubiquitously and may function in protein translocation in every living organism. This review focuses on the mammalian SRP. A brief discussion of its overall structure is followed by a detailed description of the structures of its RNA and protein constituents and the requirements for their assembly into the particle. Homologues of SRP components from organisms other than mammals are mentioned to emphasize the components' conserved or less conserved features. Subsequently, the functions of each of the SRP constituents are discussed. This sets the stage for a presentation of a model for the mechanism by which SRP cyclically assembles and disassembles with translating ribosomes and the RER membrane. It may be expected that similar mechanisms are used by SRP homologues in organisms other than mammals. However, the mammalian SRP-mediated translocation mechanism may not be conserved in its entirety in organisms like Escherichia coli whose SRP lack components required for the function of the mammalian SRP. Possible translocation pathways involving the rudimentary SRP are discussed in view of the existence of alternative, chaperone-mediated translocation pathways with which they may intersect. The concluding two sections deal with open questions in two areas of SRP research. One formulates basic questions regarding the little-investigated biogenesis of SRP. The other gives an outlook over the insights into the mechanisms of each of the known activities of the SRP that are to be expected in the short and medium-term future.

The Srp54 GTPase is essential for protein export in the fission yeast Schizosaccharomyces pombe

Signal recognition particle (SRP) is a cytoplasmic ribonucleoprotein required for targeting a subset of presecretory proteins to the endoplasmic reticulum (ER) membrane. Here we report the results of a series of experiments to define the function of the Schizosaccharomyces pombe homolog of the 54-kDa subunit of mammalian SRP. One-step gene disruption reveals that the Srp54 protein, like SRP RNA, is essential for viability in S. pombe. Precursor to the secretory protein acid phosphatase accumulates in cells in which Srp54 synthesis has been repressed under the control of a regulated promoter, indicating that S. pombe SRP functions in protein targeting. In common with other Srp54 homologs, the S. pombe protein has a modular structure consisting of an amino-terminal G (GTPase) domain and a carboxyl-terminal M (methionine-rich) domain. We have analyzed the effects of 17 site-specific mutations designed to alter the function of each of the four GTPase consensus motifs individually. Several alleles, including some with relatively conservative amino acid substitutions, confer lethal or conditional phenotypes, indicating that GTP binding and hydrolysis are critical to the in vivo role of the protein. Two mutations (R to L at position 194 [R194L] and R194H) which were designed, by analogy to oncogenic mutations in rats, to dramatically decrease the catalytic rate and one (T248N) predicted to alter nucleotide binding specificity produce proteins that are unable to support growth at 18 degrees C. Consistent with its design, the R194L mutant hydrolyzes GTP at a reduced rate relative to wild-type Srp54 in enzymatic assays on immunoprecipitated proteins. In strains that also contain wild-type srp54, this mutant protein, as well as others designed to be locked in a GTP-bound conformation, exhibits temperature-dependent dominant inhibitory effects on growth, while a mutant predicted to be GDP locked does not interfere with the function of the wild-type protein. These results form the basis of a simple model for the role of GTP hydrolysis by Srp54 during the SRP cycle.

Structural and functional characterisation of the signal recognition particle-specific 54 kDa protein (SRP54) of tomato

Two representative genes for the 54 kDa protein subunit of the signal recognition particle (SRP54) of tomato were cloned. It was shown that both genes are expressed in the tomato cv. Rentita. SRP54 is encoded by nine exons distributed over 10 kb of genomic sequence. The amino acid sequences deduced for the two SRP54 genes are 92% identical and the calculated protein size is 55 kDa. Like the homologous proteins isolated from other eukaryotes, the tomato SRP54 is evidently divided into two domains. As deduced from sequence motif identity, the N-terminally located G-domain can be assumed to have GTPase activity. The C-terminal part of the protein is methionine rich (14% methionine) and represents the M-domain. In in vitro binding experiments, SRP54 of tomato was able to attach to the 7S RNA of tomato, its natural binding partner in the SRP. This interaction can only take place in a trimeric complex consisting of 7S RNA, SRP54 and SRP19. The latter protein subunit of the SRP complex is assumed to induce a conformational change in the 7S RNA. The human SRP19 was able to mediate the binding of the tomato SRP54 to the 7S RNA, irrespective of whether this latter originated from tomato or man.

The Srp54 GTPase is essential for protein export in the fission yeast Schizosaccharomyces pombe

Signal recognition particle (SRP) is a cytoplasmic ribonucleoprotein required for targeting a subset of presecretory proteins to the endoplasmic reticulum (ER) membrane. Here we report the results of a series of experiments to define the function of the Schizosaccharomyces pombe homolog of the 54-kDa subunit of mammalian SRP. One-step gene disruption reveals that the Srp54 protein, like SRP RNA, is essential for viability in S. pombe. Precursor to the secretory protein acid phosphatase accumulates in cells in which Srp54 synthesis has been repressed under the control of a regulated promoter, indicating that S. pombe SRP functions in protein targeting. In common with other Srp54 homologs, the S. pombe protein has a modular structure consisting of an amino-terminal G (GTPase) domain and a carboxyl-terminal M (methionine-rich) domain. We have analyzed the effects of 17 site-specific mutations designed to alter the function of each of the four GTPase consensus motifs individually. Several alleles, including some with relatively conservative amino acid substitutions, confer lethal or conditional phenotypes, indicating that GTP binding and hydrolysis are critical to the in vivo role of the protein. Two mutations (R to L at position 194 [R194L] and R194H) which were designed, by analogy to oncogenic mutations in rats, to dramatically decrease the catalytic rate and one (T248N) predicted to alter nucleotide binding specificity produce proteins that are unable to support growth at 18 degrees C. Consistent with its design, the R194L mutant hydrolyzes GTP at a reduced rate relative to wild-type Srp54 in enzymatic assays on immunoprecipitated proteins. In strains that also contain wild-type srp54, this mutant protein, as well as others designed to be locked in a GTP-bound conformation, exhibits temperature-dependent dominant inhibitory effects on growth, while a mutant predicted to be GDP locked does not interfere with the function of the wild-type protein. These results form the basis of a simple model for the role of GTP hydrolysis by Srp54 during the SRP cycle.

Genetic and biochemical analysis of the fission yeast ribonucleoprotein particle containing a homolog of Srp54p

Mammalian signal recognition particle (SRP), a complex of six polypeptides and one 7SL RNA molecule, is required for targeting nascent presecretory proteins to the endoplasmic reticulum (ER). Earlier work identified a Schizosaccharomyces pombe homolog of human SRP RNA and showed that it is a component of a particle similar in size and biochemical properties to mammalian SRP. The recent cloning of the gene encoding a fission yeast protein homologous to Srp54p has made possible further characterization of the subunit structure, subcellular distribution, and assembly of fission yeast SRP. S. pombe SRP RNA and Srp54p co-sediment on a sucrose velocity gradient and coimmunoprecipitate, indicating that they reside in the same complex. In vitro assays demonstrate that fission yeast Srp54p binds under stringent conditions to E. coli SRP RNA, which consists essentially of domain IV, but not to the full-length cognate RNA nor to an RNA in which domain III has been deleted in an effort to mirror the structure of bacterial homologs. Moreover, the association of S. pombe Srp54p with SRP RNA in vivo is disrupted by conditional mutations not only in domain IV, which contains its binding site, but in domains I and III, suggesting that the particle may assemble cooperatively. The growth defects conferred by mutations throughout SRP RNA can be suppressed by overexpression of Srp54p, and the degree to which growth is restored correlates inversely with the severity of the reduction in protein binding. Conditional mutations in SRP RNA also reduce its sedimentation with the ribosome/membrane pellet during cell fractionation. Finally, immunoprecipitation under native conditions of an SRP-enriched fraction from [35S]-labeled fission yeast cells suggests that five additional polypeptides are complexed with Srp54p; each of these proteins is similar in size to a constituent of mammalian SRP, implying that the subunit structure of this ribonucleoprotein is conserved over vast evolutionary distances.