Euplotes crassus has genes encoding telomere-binding proteins and telomere-binding protein homologs.

We have identified two 1.6 kb macronuclear DNA molecules from Euplotes crassus that hybridize to the alpha subunit of the Oxytricha telomere protein. We have shown that one of these molecules encodes the 51 kDa Euplotes telomere protein while the other appears to encode a homolog of the telomere protein. Although this homolog clearly differs in sequence from the Euplotes telomere protein, the two proteins share extensive amino acid sequence identity with each other and with the alpha subunit of the Oxytricha telomere protein. In all three proteins 35-36% of the amino acids are identical, while 54-56% are similar. The most extended regions of sequence conservation map within the N-terminal section; this section has been shown to comprise the DNA-binding domain in the Euplotes telomere protein. Our findings suggest that some of the conserved amino acids may be involved in DNA recognition and binding. The gene encoding the telomere protein homolog contains two introns; one of these introns is only 24 bp in length. This is the smallest mRNA intron reported to date.     

Effect of monovalent cation-induced telomeric DNA structure on the binding of Oxytricha telomeric protein.

Oligonucleotides bearing 4 repeats of telomeric deoxyguanosine-rich sequence undergo a monovalent cation-induced transition to a folded conformation with G-G base pairs, modeled as a 'G-quartet' structure. We have now deduced the rates of folding and unfolding of d(TTTTGGGG)4, which has four repeats of the Oxytricha telomeric DNA sequence. The estimated average values of delta G for the folded form at 37 degrees C are -2.2 kcal/mol and -4.7 kcal/mol in 50 mM na+ and K+, respectively. The fully folded DNA is not recognized by the Oxytricha telomere-binding protein; the substrate for protein binding has properties consistent with its being partly or fully unfolded. In confirmation of this conclusion, prevention of DNA folding by methylation enables the protein to bind as rapidly in the presence of monovalent cations as in their absence. The slow unfolding (t1/2 = 4 hr and 18 hr at 37 degrees C in Na+ and K+, respectively) of the DNA suggests that such structures would be long-lived if they formed in vivo, unless they can be actively unfolded. The inability of the telomere-binding protein to bind the stable, folded form of the 4-repeat telomeric sequence is a problem that may be circumvented in vivo by avoiding four single-stranded repeats.     

Properties of the telomeric DNA-binding protein from Oxytricha nova

Telomeres of Oxytricha macronuclear DNA exist as discrete DNA-protein complexes. Different regions of each complex display characteristic DNA-protein interactions. In the most terminal region, binding of a 43- and a 55-kDa protein to the telomeric DNA appears to account for all the DNA-protein interactions that can be detected by chemical and nuclease footprinting. We have used gradient sedimentation and protein-protein cross-linking to establish that the 43- and 55-kDa proteins are subunits of a heterodimer. Both subunits are very basic, which is unexpected considering the resistance of the DNA-protein interaction to high concentrations of salt. It is extremely difficult to dissociate the two subunits either from telomeric DNA or from each other. Even after extensive treatment of protein preparations with nuclease, a fragment of the 3' tail from macronuclear DNA remains bound to the protein. A wide range of conditions was screened for dissociation of the subunits from the DNA and/or from each other. Dissociation was only obtained by using conditions that caused some inactivation of the DNA-binding capacity of the protein. The use of reagents that covalently modify sulfydryl groups during the purification procedure facilitates preparation of telomere protein with full DNA-binding activity.     

Crystal structure of the N-terminal domain of Oxytricha nova telomere end-binding protein alpha subunit both uncomplexed and complexed with telomeric ssDNA.

Oxytricha nova telomere end-binding protein specifically recognizes and caps single strand (T(4)G(4))(n) telomeric DNA at the very 3'-ends of O. nova macronuclear chromosomes. Proteins homologous to the N-terminal domain of OnTEBP alpha subunit have now been identified in Oxytricha trifallax, Stylonychia mytilis, Euplotes crassus, Schizosaccharomyces pombe, and Homo sapiens, suggesting that this protein is widely distributed in eukaryotes. We describe here the crystal structures of the N-terminal single-stranded DNA (ssDNA)-binding domain of O. nova telomere end-binding protein alpha subunit both uncomplexed and complexed with single strand telomeric DNA. These structures show how the N-terminal domain of alpha alone, in the absence of the beta subunit and without alpha dimerization, can bind single-stranded telomeric DNA in a sequence-specific and 3'-end-specific manner. Furthermore, comparison of the uncomplexed and complexed forms of this protein shows that the ssDNA-binding site is largely pre-organized in the absence of ssDNA with modest, but interesting, rearrangements of amino acid side-chains that compose the ssDNA-binding site. The structures described here extend our understanding of structures of O. nova telomeric complexes by adding uncomplexed and complexed forms of monomeric alpha to previously described structures for (alpha 56/ssDNA)(2) dimer and alpha 56/beta 28/ssDNA ternary complexes. We believe that each of these four structures represent intermediates in an ordered assembly/disassembly pathway for O. nova telomeric complexes.     

Molecular cloning of telomere-binding protein genes from Stylonychia mytilis.

A telomere-binding protein heterodimer of 56 kDa (alpha) and 41 kDa (beta) subunits binds specifically to Oxytricha nova telomeres. Genes encoding both subunits have been cloned previously. Here we report molecular cloning and sequence analysis of the homologous genes in Stylonychia mytilis. The derived amino acid sequences were 79% identical for the alpha subunits and 77% identical for the beta subunits. Three repeats of a Leu/Ile heptad were found in each subunit, which might be involved in heterodimer formation. A 360 amino acid region of the Stylonychia mytilis alpha subunit was found to share weak sequence similarity with human vimentin, suggesting the possibility of a relationship between telomeres and intermediate filaments.     

DNA G-quartets in a 1.86 A resolution structure of an Oxytricha nova telomeric protein-DNA complex.

The Oxytricha nova telomere end binding protein (OnTEBP) recognizes, binds and protects the single-stranded 3'-terminal DNA extension found at the ends of macronuclear chromosomes. The structure of this complex shows that the single strand GGGGTTTTGGGG DNA binds in a deep cleft between the two protein subunits of OnTEBP, adopting a non-helical and irregular conformation. In extending the resolution limit of this structure to 1.86 A, we were surprised to find a G-quartet linked dimer of the GGGGTTTTGGGG DNA also packing within the crystal lattice and interacting with the telomere end binding protein. The G-quartet DNA exhibits the same structure and topology as previously observed in solution by NMR with diagonally crossing d(TTTT) loops at either end of the four-stranded helix. Additionally, the crystal structure reveals clearly visible Na(+), and specific patterns of bound water molecules in the four non-equivalent grooves. Although the G-quartet:protein contact surfaces are modest and might simply represent crystal packing interactions, it is interesting to speculate that the two types of telomeric DNA-protein interactions observed here might both be important in telomere biology.     

The yeast telomere-binding protein RAP1 binds to and promotes the formation of DNA quadruplexes in telomeric DNA.

The protein RAP1 is essential for the maintenance of the telomeres of Saccharomyces cerevisiae and binds in vitro to multiple sites found within the TG1-3 telomeric repeats. We show here that, in addition to its known binding activity for double-stranded DNA, RAP1 binds sequence-specifically to the GT-strands. This indicates that RAP1 is the protein that binds to the telomeric terminal GT-tails. Furthermore, we have found that RAP1 binds to and promotes the formation of G-tetrads, i.e. DNA quadruplexes, in GT-strand oligonucleotides at nanomolar concentrations. The formation of DNA quadruplexes appears to involve the intermolecular association of GT-strands. The minimal DNA-binding domain of RAP1 (DBD) binds only to double-stranded DNA, so that the novel DNA-binding activity we have found involves regions of the protein located outside of the DBD. The finding that a telomeric protein promotes the formation of G-tetrads argues for the use of DNA quadruplexes in telomere association.     

Chromatin structure of the molecular ends of Oxytricha macronuclear DNA: phased nucleosomes and a telomeric complex

Oxytricha macronuclear DNA exists as approximately 24 X 10(6) gene-sized molecules terminating with a C4A4 repeat. DNA-protein interactions at the ends of bulk macronuclear molecules were probed with micrococcal nuclease and methidiumpropyl-EDTA X Fe(II) (MPE X Fe[II]). The ends were indirectly labeled by hybridizing with (C4A4)2. Alternatively, a novel method using MPE X FE(II) as a probe and directly labeling the 3' ends with terminal transferase was implemented. A terminal complex involving approximately 100 bp with nucleosomes phased inward from the complex was found to be characteristic of most or all of the ends. Analysis of two specific genes confirmed the pattern and showed that the special structure was on both ends of each molecule. We conclude that a DNA-protein complex involving 100 bp and terminating with the C4A4 repeat can be sufficient to provide the fundamental functions of telomeres, allowing linear DNA replication and conferring stability of linear DNA.     

Telomere structure in Euplotes crassus: characterization of DNA-protein interactions and isolation of a telomere-binding protein.

The nucleoprotein structure of telomeres from Euplotes crassus was studied by using nuclease and chemical footprinting. The macronuclear telomeres were found to exist as DNA-protein complexes that are resistant to micrococcal nuclease digestion. Each complex encompassed 85 to 130 base pairs of macronuclear DNA and appeared to consist of two structural domains that are characterized by dissimilar DNA-protein interactions. Dimethyl sulfate footprinting demonstrated that very sequence-specific and salt-stable interactions occur in the most terminal region of each complex. DNase I footprinting indicated that DNA in the region 30 to 120 base-pairs from the 5' end lies on a protein surface; the interactions in this region of the complex are unlikely to be sequence specific. A 50-kilodalton telomere-binding protein was isolated. Binding of this protein protected telomeric DNA from BAL 31 digestion and gave rise to many of the sequence-specific DNA-protein interactions that were observed in vivo. The telomeric complexes from E. crassus were very similar in overall structure to the complexes found at Oxytricha telomeres. However, telomeric complexes from the two ciliates showed significant differences in internal organization. The telomeric DNA, the telomere-binding proteins, and the resultant DNA-protein interactions were all somewhat different. The telomere-binding proteins from the two ciliates were found to be less closely conserved than might have been expected. It appears that the proteins are tailored to match their cognate telomeric DNA.     

Cloning and expression analysis of Phytoplasma protein translocation genes

Genes encoding SecA and SecY proteins, essential components of the Sec protein translocation system, were cloned from onion yellows phytoplasma, an unculturable plant pathogenic bacterium. The secA gene consists of 2,505 nucleotides encoding an 835 amino acid protein (95.7 kDa) and shows the highest similarity with SecA of Bacillus subtilis. Anti-SecA rabbit antibody was prepared from a purified partial SecA protein, with a histidine tag expressed in Escherichia coli. Western blot analysis confirmed that SecA protein (approximately 96 kDa) is produced in phytoplasma-infected plants. Immunohistochemical thin sections observed by optical microscopy showed that SecA is characteristically present in plant phloem tissues infected with phytoplasma. The secY gene consists of 1,239 nucleotides encoding a 413 amino acid protein (45.9 kDa) and shows the highest similarity with SecY of B. subtilis. These results suggest the presence of a functional Sec system in phytoplasmas. Because phytoplasmas are endocellular bacteria lacking cell walls, this system might secrete bacterial proteins directly into the host cytoplasm. This study is what we believe to be the first report of the sequence and expression analysis of phytoplasma genes encoding membrane proteins with a predicted function.     

Cloning and expression of the HpaI restriction-modification genes.

The genes from Haemophilus parainfluenzae encoding the HpaI restriction-modification system were cloned and expressed in Escherichia coli. From the DNA sequence, we predicted the HpaI endonuclease (R.HpaI) to have 254 amino acid residues (Mr 29,630) and the HpaI methyltransferase (M.HpaI) to have 314 amino acid residues (37,390). The R.HpaI and M.HpaI genes overlapped by 16 base pairs on the chromosomal DNA. The genes had the same orientation. The clone, named E. coli HB101-HPA2, overproduced R.HpaI. R.HpaI activity from the clone was 100-fold that from H. parainfluenzae. The amino acid sequence of M.HpaI was compared with those of other type II methyltransferases.     

Structure and functional expression of the acid-labile subunit of the insulin-like growth factor-binding protein complex.

Nearly all of the insulin-like growth factor (IGF) in the circulation is bound in a heterotrimeric complex composed of IGF, IGF-binding protein-3, and the acid-labile subunit (ALS). Full-length clones encoding ALS have been isolated from human liver cDNA libraries by using probes based on amino acid sequence data from the purified protein. These clones encode a mature protein of 578 amino acids preceded by a 27-amino acid hydrophobic sequence indicative of a secretion signal. Expression of the cDNA clones in mammalian tissue culture cells results in the secretion into the culture medium of ALS activity that can form the expected complex with IGF-I and IGF-binding protein-3. The amino acid sequence of ALS is largely composed of 18-20 leucine-rich repeats of 24 amino acids. These repeats are found in a number of diverse proteins that, like ALS, participate in protein-protein interactions.     

Suppression of telomere-binding protein gene expression represses seed and fruit development in tomato

Tomato (Solanum lycopersicum L.) plants were transformed with an antisense construct of a cDNA encoding tomato telomere-binding protein (LeTBP1) to describe the role of a telomere-binding protein at the whole plant level. Fruit size decreased corresponding to the degree of suppression of LeTBP1 expression. This inhibition of fruit development was likely due to a decrease in the number of seeds in the LeTBP1 antisense plants. Pollen fertility and pollen germination rate decreased in accordance with the degree of suppression of LeTBP1 expression. Ovule viability was also reduced in the LeTBP1 antisense plants. Although plant height was somewhat reduced in the antisense plants compared to the control plants, the number and weight of leaves were unaffected by LeTBP1 suppression. The number and morphology of flowers were also normal in the antisense plants. These indicate that reduced fertility in the antisense plants is not an indirect effect of altered vegetative growth. LeTBP1 expression was sensitive to temperature stress in wild-type plants. We conclude that LeTBP1 plays a critical role in seed and fruit development rather than vegetative growth and flower formation.     

Mycoplasmas regulate the expression of heat-shock protein genes through CIRCE-HrcA interactions

Mycoplasmas in general are rarely exposed to severe environmental changes except during its colonization and infection processes. Genomic analysis indicates that Mycoplasma hyopneumoniae possesses the genes of a single sigma factor and the HrcA repressor of negative regulation of the heat-shock response. A perfect inverted repeat sequence (5′-CTGGCACTT-N₉-AAGTGCCAA-3′) upstream of the DnaK gene has also been identified. In the present study, we demonstrate the functionality of HrcA-CIRCE interactions using the gel electrophoretic mobility shift assay. The presence of the unique sigma factor, HrcA repressor, and the CIRCE-like sequences reveals that mycoplasmal species may all use the negative regulatory mechanism in the heat-shock response. It is conceivable that mycoplasmas may have evolved a single HrcA repressor-based mechanism which might be the most simple and economical way of controlling HSP gene expression.     

Specificity of G protein beta and gamma subunit interactions.

Multiple heterotrimeric guanine nucleotide binding protein (G protein) subunits have evolved to couple a large variety of receptors to intracellular effectors. G protein beta gamma subunits are essential for efficient coupling of alpha subunits to receptors, and they are also important for modulation of effectors. Several different beta and gamma subunits exist, but it is not known whether all possible combinations of beta and gamma can form functional dimers. To answer this question, we have compared the ability of in vitro translated beta 1, beta 2, and beta 3 to form dimers with either gamma 1 or gamma 2. Dimerization was monitored by gel filtration, resistance to tryptic digestion, and chemical cross-linking. The results indicate that beta 1 binds both gamma subunits, beta 2 binds only gamma 2, and beta 3 will bind neither gamma 1 or gamma 2. Hence, the occurrence of beta gamma dimers may be partially regulated by the ability of the subunits to associate. Specificity of dimerization might allow cells to co-express multiple beta and gamma subunits while maintaining efficient and specific signal transduction.     

Cloning and expression of an intron-less gene for AKAP 75, an anchor protein for the regulatory subunit of cAMP-dependent protein kinase II beta.

The A-Kinase Anchor Protein AKAP 75 (formerly designated bovine brain P75) is a particulate brain protein that avidly binds the regulatory subunit (RII beta) of cAMP-dependent protein kinase II beta (Bregman, D. B., Hirsch, A.H. and Rubin, C.S. (1991) J. Biol. Chem. 266, 7207-7213). The formation of stable AKAP 75.RII beta complexes provides a potential mechanism for targeting physiological signals carried by cAMP to specific effector sites within neurons and other brain cells. We have now cloned and characterized the AKAP 75 gene. Its coding sequence is novel and unexpectedly short (1284 base pairs) and contains no introns. When the AKAP 75 gene was transfected into HEK 293 cells, a new RII beta-binding protein with an apparent Mr of 75,000 accumulated. A high proportion (approximately 65%) of the AKAP 75 gene product was excluded from the cytoplasm and was recovered in the 40,000 x g pellet derived from disrupted transfected cells. In contrast, cells transfected with a construct encoding 249 amino acids from the central and C-terminal regions of AKAP 75 produced an RII beta-binding protein (apparent Mr = 45,000) that was exclusively cytosolic. AKAP 75 is a novel protein composed of only 428 amino acid residues (Mr = 47,878). A highly acidic C-terminal region mediates the binding of RII beta (and cAMP-dependent protein kinase II beta), whereas a positively charged N-terminal segment contains structural features that are essential for the association of AKAP 75 with the cytoskeleton and/or intracellular membranes.