Hydroxypyruvate Reductase with a Carboxy-Terminal Targeting Signal to Microbodies is Expressed in Arabidopsis

Five Arabidopsis EST cDNA clones of hydroxypyruvate reductase(HPR), a photorespiratory enzyme in leaf peroxisomes, were sequenced.Deduced amino acid sequences revealed that HPR in Arabidopsiscontained the carboxy-terminal targeting signal to microbodies.Nucle-otide sequence analysis showed that the cDNA with thelongest insert contained an open reading frame of 1,158 bp whichencoded a polypeptide with 386 amino acids with a calculatedmolecular mass of 42,251 Da. A Southern blot analysis suggestedthat the Arabidopsis HPR gene, like that of the pumpkin HPRgene, exists as a single copy. Two kinds of pumpkin HPR mRNAmight be produced from a single gene by alternative splicing,but the structure of the genomic DNA indicated that the ArabidopsisHPR gene did not undergo alternative splicing. We detected apolypeptide with a molecular mass of 42 kDa in green leavesof Arabidopsis using an HPR-specific antibody. Immunoelectronmicroscopy revealed that Arabidopsis HPR protein was exclusivelylocalized in leaf peroxisomes in green leaves. These resultsindicate that HPR is expressed in a form with a carboxy-terminaltargeting signal to microbodies and is localized in microbodiesin Arabidopsis, suggesting that the differences in the genestructure and the regulation of gene expression of HPR are probablydue to species-specific differences in plants. (Received November 11, 1996; Accepted February 1, 1997)     

cDNA cloning and differential gene expression of three catalases in pumpkin

Three cDNA clones (cat1, cat2, cat3) for catalase (EC 1.11.1.6) were isolated from a cDNA library of pumpkin (Cucurbita sp.) cotyledons. In northern blotting using the cDNA-specific probe, the cat1 mRNA levels were high in seeds and early seedlings of pumpkin. The expression pattern of cat1 was similar to that of malate synthase, a characteristic enzyme of glyoxysomes. These data suggest that cat1 might encode a catalase associated with glyoxysomal functions. Furthermore, immunocytochemical analysis using cat1-specific anti-peptide antibody directly showed that cat1 encoding catalase is located in glyoxysomes. The cat2 mRNA was present at high levels in green cotyledons, mature leaf, stem and green hypocotyl of light-grown pumpkin plant, and correlated with chlorophyll content in the tissues. The tissue-specific expression of cat2 had a strong resemblance to that of glycolate oxidase, a characteristic enzyme of leaf peroxisomes. During germination of pumpkin seeds, cat2 mRNA levels increased in response to light, although the increase in cat2 mRNA by light was less than that of glycolate oxidase. cat3 mRNA was abundant in green cotyledons, etiolated cotyledons, green hypocotyl and root, but not in young leaf. cat3 mRNA expression was not dependent on light, but was constitutive in mature tissues. Interestingly, cat1 mRNA levels increased during senescence of pumpkin cotyledons, whereas cat2 and cat3 mRNAs disappeared during senescence, suggesting that cat1 encoding catalase may be involved in the senescence process. Thus, in pumpkin, three catalase genes are differentially regulated and may exhibit different functions.     

Proteomic analysis of leaf peroxisomal proteins in greening cotyledons of Arabidopsis thaliana

Leaf peroxisomes are present in greening cotyledons and contain enzymes of the glycolate pathway that functions in photorespiration. However, only a few leaf peroxisomal proteins, that is hydroxypyruvate reductase (HPR), glycolate oxidase (GO) and alanine:glyoxylate aminotransferase 1 (AGT1), have been characterized, and other functions in leaf peroxisomes have not been solved. To better understand the functions of leaf peroxisomes, we established a method to isolate leaf peroxisomes of greening cotyledons. We analyzed 53 proteins by MALDI-TOF MS and then identified 29 proteins. Among them, five proteins are related to the glycolate pathway, four proteins function in scavenging of hydrogen peroxide and additionally 20 novel leaf peroxisomal proteins were identified. In particular, protein kinases and protein phosphatase were first identified as peroxisomal proteins suggesting that protein phosphorylation is one of the regulatory mechanisms in leaf peroxisomes. Novel leaf peroxisomal proteins contained five PTS1-like proteins that have sequences where one amino acid is substituted with another one in PTS1 sequences. The PTS1 motif was suggested to have novel PTS1 sequences.     

Pumpkin hydroxypyruvate reductases with and without a putative C-terminal signal for targeting to microbodies may be produced by alternative splicing

Two full-length cDNAs encoding hydroxypyruvate reductase were isolated from a cDNA library constructed with poly(A)⁺ RNA from pumpkin green cotyledons. One of the cDNAs, designated HPR1, encodes a polypeptide of 386 amino acids, while the other cDNA, HPR2 encodes a polypeptide of 381 amino acids. Although the nucleotide and deduced amino acid sequences of these cDNAs are almost identical, the deduced HPR1 protein contains Ser-Lys-Leu at its carboxy-terminal end, which is known as a microbody-targeting signal, while the deduced HPR2 protein does not. Analysis of genomic DNA strongly suggests that HPR1 and HPR2 are produced by alternative splicing.     

A suboptimal 5' splice site is a cis-acting determinant of nuclear export of polyomavirus late mRNAs.

Mouse polyomavirus has been used as a model system to study nucleocytoplasmic transport of mRNA. Three late mRNAs encoding the viral capsid proteins are generated by alternative splicing from common pre-mRNA molecules. mRNAs encoding the virion protein VP2 (mVP2) harbor an unused 5' splice site, and more than half of them remain fully unspliced yet are able to enter the cytoplasm for translation. Examination of the intracellular distribution of late viral mRNAs revealed, however, that mVP2 molecules are exported less efficiently than are mVP1 and mVP3, in which the 5' splice site has been removed by splicing. Point mutations and deletion analyses demonstrated that the efficiency of mVP2 export is inversely correlated with the strength of the 5' splice site and that unused 3' splice sites present in the mRNA have little or no effect on export. These results suggest that the unused 5' splice site is a key player in mVP2 export. Interestingly, mRNAs carrying large deletions but retaining the 5' splice site exhibited a wild-type mVP2 export phenotype, suggesting that there are no other constitutive cis-acting sequences involved in mVP2 export. RNA stability measurements confirmed that the subcellular distribution differences between these mRNAs were not due to differential half-lives between the two cellular compartments. We therefore conclude that the nuclear export of mVP2 is strongly influenced by a suboptimal 5' splice site. Furthermore, results comparing spliced and unspliced forms of mVP2 molecules indicated that the process of splicing does not enhance nuclear export. Since mVP2 and some of its mutant forms can accumulate in the cytoplasm in the absence of splicing, we propose that splicing is not a prerequisite for mRNA export in the polyomavirus system; rather, removal of splicing machinery from mRNAs may be required. The possibility that export of other viral mRNAs can be influenced by suboptimal splicing signals is also discussed.     

Myelin-Associated Oligodendrocytic Basic Protein mRNAs Reside at Different Subcellular Locations

The mRNAs for two myelin proteins, myelin basic protein (MBP) and myelin-associated oligodendrocytic basic protein (MOBP)-81A, are uniquely located at sites where myelin sheaths are assembled. Here, we use subcellular fractionation to show that four MOBP mRNAs, like MBP mRNA, are located at sites of myelin sheath assembly, and that three other MOBP mRNAs are located in oligodendrocyte soma. The MOBP-81 protein is found in myelin and in another subcellular fraction, whereas other myelin proteins, including MBP, 2',3'-cyclic nucleotide 3'-phosphodiesterase, and myelin-associated glycoprotein, are largely restricted to myelin. Different MBP mRNAs are generated by alternative splicing. All of them contain an RNA transport sequence (RTS) that directs them to sites in oligodendrocytes, where myelin sheaths are assembled. Consequently, all are enriched in myelin. After fractionation, four MOBP mRNAs, MOBP-71, MOBP-81A, MOBP-99, and MOBP-169 (identified in this study), are enriched in myelin. These mRNAs contain a common exon, exon 8b, which has a nucleotide sequence that is similar to MBP mRNA RTS. This sequence likely directs these mRNAs to sites of myelin sheath assembly. Three other MOBP mRNAs, MOBP-69, MOBP-81B, and MOBP-170, lack this exon. Their subcellular distribution indicates that they are largely retained in oligodendrocyte soma. We conclude that the distribution of MOBPs in oligodendrocytes is strongly influenced by alternative splicing of the corresponding mRNAs.     

Targeting a heterologous protein to multiple plant organelles via rationally designed 5′ mRNA tags

Background

Plant bioengineers require simple genetic devices for predictable localization of heterologous proteins to multiple subcellular compartments.

Results

We designed novel hybrid signal sequences for multiple-compartment localization and characterize their function when fused to GFP in Nicotiana benthamiana leaf tissue. TriTag-1 and TriTag-2 use alternative splicing to generate differentially localized GFP isoforms, localizing it to the chloroplasts, peroxisomes and cytosol. TriTag-1 shows a bias for targeting the chloroplast envelope while TriTag-2 preferentially targets the peroxisomes. TriTag-3 embeds a conserved peroxisomal targeting signal within a chloroplast transit peptide, directing GFP to the chloroplasts and peroxisomes.

Conclusions

Our novel signal sequences can reduce the number of cloning steps and the amount of genetic material required to target a heterologous protein to multiple locations in plant cells. This work harnesses alternative splicing and signal embedding for engineering plants to express multi-functional proteins from single genetic constructs.

     

Alternative splicing during chondrogenesis: modulation of fibronectin exon EIIIA splicing by SR proteins

The alternative exon EIIIA of the fibronectin gene is included in mRNAs produced in undifferentiated mesenchymal cells but excluded from differentiated chondrocytes. As members of the SR protein family of splicing factors have been demonstrated to be involved in the alternative splicing of other mRNAs, the role of SR proteins in chondrogenesis-associated EIIIA splicing was investigated. SR proteins interacted with chick exon EIIIA sequences that are required for exon inclusion in a gel mobility shift assay. Addition of SR proteins to in vitro splicing reactions increased the rate and extent of exon EIIIA inclusion. Co-transfection studies employing cDNAs encoding individual SR proteins revealed that SRp20 decreased mRNA accumulation in HeLa cells, which make A+ mRNA, apparently by interfering with pre-mRNA splicing. Co-transfection studies also demonstrated that SRp40 increased exon EIIIA inclusion in chondrocytes, but not in HeLa cells, suggesting the importance of cellular context for SR protein activity. Immunoblot analysis did not reveal a relative depletion of SRp40 in chondrocytic cells. Possible mechanisms for regulation of EIIIA splicing in particular, and chondrogenesis associated splicing in general, are discussed.     

Molecular characterization of a second copy of holocarboxylase synthetase gene (hcs2) in Arabidopsis thaliana.

Holocarboxylase synthetase (HCS), catalyzing the covalent attachment of biotin, is ubiquitously represented in living organisms. Indeed, the biotinylation is a post-translational modification that allows the transformation of inactive biotin-dependent carboxylases, which are committed in fundamental metabolisms such as fatty acid synthesis, into their active holo form. Among other living organisms, plants present a peculiarly complex situation. In pea, HCS activity has been detected in three subcellular compartments and the systematic sequencing of the Arabidopsis genome revealed the occurrence of two hcs genes (hcs1 and hcs2). Hcs1 gene product had been previously characterized at molecular and biochemical levels. Here, by PCR amplification, we cloned an hcs2 cDNA from Arabidopsis thaliana (Ws ecotype) mRNA. We observed the occurrence of multiple cDNA forms which resulted from the alternative splicing of hcs2 mRNA. Furthermore, we evidenced a nucleotide polymorphism at the hcs2 gene within the Ws ecotype, which affected splicing of hcs2 mRNA. This contrasted sharply with the situation at hcs1 locus. However, this polymorphism had no apparent effect on total HCS activity in planta. Finally, hcs2 mRNAs were found 4-fold less abundant than hcs1 mRNA and the most abundant hcs2 mRNA spliced variant should code for a truncated protein. We discuss the possible role of such a multiplicity of putative HCS proteins in plants and discuss the involvement of each of hcs genes in the correct realization of biotinylation.     

UPF3 suppresses aberrant spliced mRNA in Arabidopsis

It has been reported that eukaryotic organisms have a nonsense-mediated mRNA decay (NMD) system to exclude aberrant mRNAs that produce truncated proteins. NMD is an RNA surveillance pathway that degrades mRNAs possessing premature translation termination codons (PTCs), thus avoiding production of possibly toxic truncated proteins. Three interacting proteins, UPF1, UPF2 and UPF3, are required for NMD in mammals and yeasts, and their amino acid sequences are well conserved among most eukaryotes, including plants. In this study, 'The Arabidopsis Information Resource' database was searched for mRNAs with premature termination codons. We selected five of these mRNAs and checked for the presence of PTCs in these mRNAs when translated in vivo. As a result we identified aberrant mRNAs produced by alternative splicing for each gene. These genes produced at least one alternative splicing variant including a PTC (PTC+) and another variant without a PTC (PTC-). We analyzed their PTC+/PTC- ratios in wild-type Arabidopsis and upf3 mutant plants and showed that the PTC+/PTC- ratios were higher in atupf3 mutant plants than wild-type plants and that the atupf3 mutant was less able to degrade mRNAs with premature termination codons than wild-type plants. This indicated that the AtUPF3 gene is required by the plant NMD system to obviate aberrantly spliced mRNA.     

Heterologous C-terminal signals effectively target fluorescent fusion proteins to leaf peroxisomes in diverse plant species

Peroxisomes are functionally diverse organelles that are wholly dependent on import of nuclear-encoded proteins. The signals that direct proteins into these organelles are either found at the C-terminus (type 1 peroxisomal targeting signal; PTS1) or N-terminus (type 2 peroxisomal targeting signal; PTS2) of the protein. Based on a limited number of tests in heterologous systems, PTS1 signals appear to be conserved across species. To further test the generality of this conclusion and to establish the extent to which the PTS1 signals can be relied on for biotechnological purposes across species, we tested two PTS1 signals for their ability to target fluorescent proteins in diverse plant species. Transient assays following microprojectile bombardment showed that the six amino acid PTS1 sequence (RAVARL) from spinach glycolate oxidase effectively targets green fluorescent fusion protein to the leaf peroxisomes in all 20 crops tested, including four monocots (sugarcane, wheat, corn and onion) and 16 dicots (carrot, cucumber, broccoli, tomato, lettuce, turnip, radish, cauliflower, cabbage, capsicum, celery, tobacco, petunia, beetroot, eggplant and coriander). Similarly, results indicated that the 10 amino acid PTS1 sequence (IHHPRELSRL) from pumpkin malate synthase effectively targets red fluorescent fusion protein to the leaf peroxisomes in all four crops tested including monocot (sugarcane) and dicot (cabbage, celery and pumpkin) species. These signal sequences should be useful metabolic engineering tools to direct recombinant proteins to the leaf peroxisomes in diverse plant species of biotechnological interest.     

Gene response upon illumination in forming mRNA encoding peroxisomal glycollate oxidase

Glycollate oxidase is a constituent of leaf peroxisomes. Its biosynthesis is, like the biosynthesis of many chloroplastic proteins, controlled by light, via phytochrome. The level of mRNA coding for glycollate oxidase was determined at different stages of greening of etiolated plant cells. The appearance of glycollate oxidase mRNA in the cytoplasm was measured by hybridization with cDNA containing part of the coding sequence for glycollate oxidase. cDNA was prepared from enriched mRNA, inserted into the Pst I site of pBR 322, and cloned in Escherichia coli DH-1. By differential colony hybridization and hybrid selection, a clone containing a 670 bp sequence complementary to mRNA encoding glycollate oxidase was selected and identified. Northern blot hybridization was used to investigate mRNA levels induced by light. It was found that continuous light affected the formation of glycollate oxidase mRNA. When a large population of microbodies was present in the cells being induced, the immediate mRNA increase was very pronounced, and was detectable as little as 20 min after the beginning of the light treatment. In contrast, a lag period in the mRNA increase was observed when the induction was performed with etiolated leaves which are characterized by the occurrence of a rather small population of microbodies. For comparison, we measured the time-course of formation of mRNA coding for a light-induced chloroplastic protein, i.e., a protein of the light-harvesting complex. The time-courses of levels of the two mRNAs indicate that the program of gene expression differs between the two particular proteins destined either for chloroplasts or for peroxisomes. The formation of glycollate oxidase mRNA could also be stimulated by a short pulse of light, a treatment of 15 s being a sufficient trigger.     

Identification of a cis element for tissue-specific alternative splicing of chloroplast ascorbate peroxidase pre-mRNA in higher plants

Alternative splicing events in the 3'-terminal region of chloroplast ascorbate peroxidase (chlAPX) pre-mRNA in spinach and tobacco, which produced four types of mRNA variants, one form (tAPX-I) encoding thylakoid-bound APX (tAPX) and three forms (sAPX-I, -II, and -III) encoding stromal APX (sAPX), were regulated in a tissue-specific manner. The ratio of the level of sAPX mRNAs (sAPX-I, -II, and -III) to tAPX-I mRNA was close to 1 in leaf, whereas the ratio in root was greatly elevated due to an increase in sAPX-III and a decrease in tAPX-I resulting from the alternative excision of intron 11 and intron 12, respectively. A putative splicing regulatory cis element (SRE), which is highly conserved in the sequences of chlAPX genes of higher plants, was identified upstream of the acceptor site in intron 12. The deletion of the SRE sequence diminished the splicing efficiency of intron 12 in tobacco leaf in vivo. Gel-shift analysis showed that SRE interacts strongly with a nuclear protein from leaves but not those from the roots of spinach and tobacco. These results indicate that the tissue-specific alternative splicing of chlAPX pre-mRNA is regulated by the splicing enhancer SRE.     

Two alternatively spliced mouse urokinase receptor mRNAs with different histological localization in the gastrointestinal tract

Two mouse urokinase-type plasminogen activator receptor (muPAR) cDNAs were isolated: muPAR1 is homologous to the human urokinase-type plasminogen activator receptor while muPAR2 codes for a 199 residue protein sharing the first 133 residues with muPAR1. Mouse genomic DNA sequencing indicates that the two different mRNAs arise by alternative splicing. In situ hybridization showed differential expression of the two mRNAs in mouse gastric mucosa. muPAR1 mRNA is located in luminal epithelial cells situated close to urokinase-type plasminogen activator-producing connective tissue cells of the lamina propria, pointing to plasmin generation controlled by the cooperation of different cells that may play a role in the release of gastric epithelial cells. muPAR2 mRNA is expressed in the basal epithelial cells, and the deduced protein sequence includes the receptor ligand binding domain, but omits the region involved in glycolipid-mediated membrane anchoring, suggesting that muPAR2 may code for a secreted uPA binding protein.