Spermine metabolism and anticancer therapy.

The natural polyamines (PA), putrescine (PUT), spermidine (SPD) and spermine (SPM) are ubiquitous constituents of eukaryotic cells. The increase of PA in malignant and proliferating cells attracted the interest of scientists during last decades, addressing PA depletion as a new strategy to inhibit cell growth. Selective enzyme inhibitors were developed for decreasing PA metabolism and to act as chemotherapeutic anticancer agents. Indeed, the complexity of the PA homoeostasis overcomes the PA perturbation by a single enzyme to take effect therapeutically. Recently, an increasing interest has been posed on spermine-oxidase (SMO), the only catabolic enzyme able to specifically oxidise SPM. Interestingly, the absence of SPM is compatible with life, but its accumulation and degradation is lethal. Augmented SMO activity provokes an oxidative stress rendering cells prone to die, and appears to be important in the cell differentiation pathway. Extra-cellular SPM is cytotoxic, but its analogues are capable of inhibiting cell growth at low concentrations, most likely by intracellular SPM depletion. These pivotal roles seem to evoke the biological processes of stress response, wherein balance is mandatory to live or to die. Thus, altering SPM metabolism could allow a multi-tasking therapeutic strategy, addressed not only to inhibit PA metabolism. Several tetramines are presently in early phases (I and II) of clinical trials, and it will be a matter of a few more years to understand whether SPM-related therapeutic approaches would be of benefit for composite treatment protocols of cancer.

Chronic sub-lethal oxidative stress by spermine oxidase overactivity induces continuous DNA repair and hypersensitivity to radiation exposure.

In the aging process and in most degenerative diseases, the oxidant by-products of cellular metabolism lead to oxidative stress. Oxidative stress plays an important role in switching from cell proliferation to its opposite outcome, cell death. The metabolic pathways in charge of the interconversion and degradation of the polyamines are responsible for oxidant by-products. In the past few years, spermine metabolism has been found closely related to DNA oxidation and apoptosis. Moreover, that the ectopical expression of murine spermine oxidase induced DNA damage in the neuroblastoma cell line, and this was uncoupled with any increase in cell mortality, thus suggests an activation of DNA repair. In this work, we provide new evidence showing that only spermine oxidase overactivity can deliver sub-lethal chronic DNA damage and repair without affecting transcriptional and enzymatic levels of the PA key regulatory enzymes ODC and SSAT. Chronic sub-lethal DNA damage is below the cell cycle arrest induction threshold, but is able to activate apurinic/apyrimidinic endonuclease protein (APE1) and gamma H2AX. Of therapeutic interest, the chronic sub-lethal DNA damage and activation of the repair processes are in turn responsible for inducing hypersensitivity after exposure to radiation with no induction of adaptive response to damage.

Direct oxidative DNA damage, apoptosis and radio sensitivity by spermine oxidase activities in mouse neuroblastoma cells.

In mammals, the polyamines affect cell growth, differentiation, and apoptosis; their levels are increased in malignant and proliferating cells, thus justifying an interest in a chemotherapeutic approach to cancer. The flavoprotein SMO is the most recently characterized catabolic enzyme, preferentially oxidizing SPM to SPD, 3-aminopropanal and H(2)O(2). In this report, we describe a novel functional characterization of the recently cloned splice variant isoforms from mouse brain, encoding, among others, the nuclear co-localized spermine oxidase mSMOmu. The over-expression of the active isoforms mSMOalpha and mSMOmu, and the inactive mSMOdelta and mSMOgamma in mouse neuroblastoma cells, demonstrated the first evidence of the direct oxidative DNA damage by the SMO activities, either alone or, in a higher extent, when associated with radiation exposure, thus working as radio sensitizer. These effects were reverted by treatment with 50 muM and 100 muM doses of the inhibitor of SMO activity MDL 72,527. The over-expression of all SMO isoforms failed to influence the expression of the regulating enzymes of polyamines metabolism ODC and SSAT. Dealing with the unbalanced tissue specific SMO activities, these results could indicate a new direction to tailor chemotherapy-associated radiotherapy, improving dose-rate protocol and allowing the modulation of deleterious side effects on healthy tissues.

A barley polyamine oxidase isoform with distinct structural features and subcellular localization.

Two cDNAs encoding polyamine oxidase (PAO) isoforms (BPAO1 and BPAO2) and the corresponding gene copies were isolated from barley cultivar Aura. Gene organization is not conserved between these two nonallelic coding sequences. Both precursor proteins include a cleavable N-terminal leader of 25 amino acids. N-terminal sequencing of PAO purified from barley seedlings reveals a unique amino-acid sequence corresponding to the BPAO2 N-terminus as predicted from the corresponding cDNA. BPAO2 has been purified, characterized and compared to maize PAO (MPAO), the best characterized member of this enzyme class. The two proteins show different pH optima for catalytic activity, Km and Vmax values with spermidine and spermine as substrates. Molecular modelling of BPAO2 reveals the same global fold as in MPAO. However, substitution of the active site residue Phe403 by a tyrosine, provides a rationale for the different catalytic properties of the two enzymes. In barley leaves PAO-specific activity is higher in isolated mesophyll protoplasts than in the extracellular fluids, whereas in maize the reverse is true. The C-terminus of BPAO2 shows homology with the endoplasmic reticulum retention signal that might be responsible for the subcellular localization observed. We conclude that BPAO2 is a symplastic PAO in barley mesophyll cells. Production of BPAO2 mRNA and the corresponding protein is induced by light, and has a different pattern of accumulation in leaves and coleoptiles.

Expression of the gene for mitoribosomal protein S12 is controlled in human cells at the levels of transcription, RNA splicing, and translation.

The human gene RPMS12 encodes a protein similar to bacterial ribosomal protein S12 and is proposed to represent the human mitochondrial orthologue. RPMS12 reporter gene expression in cultured human cells supports the idea that the gene product is mitochondrial and is localized to the inner membrane. Human cells contain at least four structurally distinct RPMS12 mRNAs that differ in their 5'-untranslated region (5'-UTR) as a result of alternate splicing and of 5' end heterogeneity. All of them encode the same polypeptide. The full 5'-UTR contains two types of sequence element implicated elsewhere in translational regulation as follows: a short upstream open reading frame and an oligopyrimidine tract similar to that found at the 5' end of mRNAs encoding other growth-regulated proteins, including those of cytosolic ribosomes. The fully spliced (short) mRNA is the predominant form in all cell types studied and is translationally down-regulated in cultured cells in response to serum starvation, even though it lacks both of the putative translational regulatory elements. By contrast, other splice variants containing one or both of these elements are not translationally regulated by growth status but are translated poorly in both growing and non-growing cells. Reporter analysis identified a 26-nucleotide tract of the 5'-UTR of the short mRNA that is essential for translational down-regulation in growth-inhibited cells. Such experiments also confirmed that the 5'-UTR of the longer mRNA variants contains negative regulatory elements for translation. Tissue representation of RPMS12 mRNA is highly variable, following a typical mitochondrial pattern, but the relative levels of the different splice variants are similar in different tissues. These findings indicate a complex, multilevel regulation of RPMS12 gene expression in response to signals mediating growth, tissue specialization, and probably metabolic needs.

Maize polyamine oxidase: primary structure from protein and cDNA sequencing.

The first complete amino acid sequence of a flavin-containing polyamine oxidase was solved by a combined approach of nucleotide and peptide sequence analysis. A cDNA of 1737 bp, isolated from maize seedlings by reverse transcription-polymerase chain reaction and rapid amplification of cDNA ends strategies, was cloned and its sequence determined. This cDNA contains information for a polypeptide chain of 500 amino acids. Its amino-terminal sequence shows the typical features of secretion signal peptides. The primary structure of the mature protein was independently confirmed by extensive amino acid sequencing. Structural relationships with flavin-containing monoamine oxidases are also discussed.

Fugu intron oversize reveals the presence of U15 snoRNA coding sequences in some introns of the ribosomal protein S3 gene.

We present here the analysis of the genomic organization of the Fugu gene coding for ribosomal protein S3 and its intron encoded U15 RNA, and compare it with the homologous human and Xenopus genes. Only two of the six Fugu S3 gene introns do not contain the U15 sequence and are in fact shorter than 100 nucleotides, as most Fugu introns. The other four introns are somewhat longer and contain sequences homologous to U15 RNA; two of these represent functional copies, as shown by microinjections of Fugu transcripts into Xenopus oocytes, whereas the other two appear to be nonfunctional pseudocopies. Thus Fugu turns out to be ideal for the study of intron encoded snoRNAs, partly because of the reduced cloning and sequencing workload, and partly because the intron length per se can be an indication of the presence of a snoRNA coding sequence.

A functional role for some Fugu introns larger than the typical short ones: the example of the gene coding for ribosomal protein S7 and snoRNA U17.

The compact genome of Fugu rubripes, with its very small introns, appears to be particularly suitable to study intron-encoded functions. We have analyzed the Fugu gene for ribosomal protein S7 (formerly S8, see Note), whose Xenopus homolog contains in its introns the coding sequences for the small nucleolar RNA U17. Except for intron length, the organization of the Fugu S7 gene is very similar to that of the Xenopus counterpart. The total length of the Fugu S7 gene is 3930 bp, compared with 12691 bp for Xenopus. This length difference is uniquely due to smaller introns. Although short, the six introns are longer than the approximately 100 bp size of most Fugu introns, as they host U17 RNA coding sequences. While four of the six U17 sequences are 'canonical', the remaining two represent diverged U17 pseudocopies. In fact, microinjection in Xenopus oocytes of in vitro synthesized Fugu transcripts containing the 'canonical' U17f sequence results in efficient production of mature U17 RNA, while injection of a transcript containing the U17 psi b sequence does not.

Structure and expression of ribosomal protein genes in Xenopus laevis.

In Xenopus laevis, as well as in other vertebrates, ribosomal proteins (r-proteins) are coded by a class of genes that share some organizational and structural features. One of these, also common to genes coding for other proteins involved in the translation apparatus synthesis and function, is the presence within their introns of sequences coding for small nucleolar RNAs. Another feature is the presence of common structures, mainly in the regions surrounding the 5' ends, involved in their coregulated expression. This is attained at various regulatory levels: transcriptional, posttranscriptional, and translational. Particular attention is given here to regulation at the translational level, which has been studied during Xenopus oogenesis and embryogenesis and also during nutritional changes of Xenopus cultured cells. This regulation, which responds to the cellular need for new ribosomes, operates by changing the fraction of rp-mRNA (ribosomal protein mRNA) engaged on polysomes. A typical 5' untranslated region characterizing all vertebrate rp-mRNAs analyzed to date is responsible for this translational behaviour: it is always short and starts with an 8-12 nucleotide polypyrimidine tract. This region binds in vitro some proteins that can represent putative trans-acting factors for this translational regulation.

The Xenopus intron-encoded U17 snoRNA is produced by exonucleolytic processing of its precursor in oocytes.

U17 is a small nucleolar RNA encoded in the introns of the Xenopus laevis gene for ribosomal protein S7 (formerly S8, see Note). To study the mechanisms involved in its in vivo processing from S7 transcripts, various in vitro synthesized RNAs embedding a U17 sequence have been microinjected into the germinal vesicle of Xenopus oocytes and their processing analysed. In particular, the Xenopus U17 gene copies a and f and a U17 gene copy from the pufferfish Fugu rubripes have been used. Information about the nature of the processing activities involved in U17 RNA maturation have been sought by injecting transcripts protected from exonucleolytic attack at their 5'-end by capping and/or lengthened at their 3'-end by polyadenylation. The results obtained indicate that U17 RNA processing is a splicing-independent event and that it is mostly or entirely due to exonucleolytic degradation at both the 5'- and 3'-ends of the precursor molecules. Moreover, it is concluded that the enzymes involved are of the processive type. It is suggested that the apparatus for U17 RNA processing is that responsible for the degradation of all excised and debranched introns. Protection from exonucleolytic attack, due to the tight structure and/or to the binding of specific proteins, would be the mechanism by which U17 RNA is produced.

Unique features in the mitochondrial D-loop region of the European seabass Dicentrarchus labrax.

We have cloned and sequenced the displacement-loop (D-loop) region of the mitochondrial DNA (mtDNA) from the European seabass Dicentrarchus labrax (Dl). This sequencing revealed the presence of four tandemly repeated elements (R1, R2, R3 and R4); the individual variation in mtDNA total length is entirely accounted for by their variable number. The individuals examined also possessed an imperfect copy of one of the tandem repeats (psi R2). At least one termination-associated sequence (TAS) is present in each of the repeats and in two copies 5' upstream from the tandem array as well. The alignment of the Dl D-loop region with D-loop sequences from four other Teleosts and one Chondrosteus showed the Dl sequence to be larger than that of other fish. The extraordinary length of the Dl D-loop sequence is also due to the 5' and 3' regions that are flanking the tandem array, the largest ones to date analyzed in fish. In this study, we also report the unique organization and localization of putative TAS and conserved-sequence block (CSB) elements, and the presence of a conserved 218-bp sequence in the Dl D-loop region.

Xenopus laevis ribosomal protein S11: cloning and sequencing of the cDNA and primary structure of the protein.

We have cloned a Xenopus laevis cDNA coding for the 40S subunit cytoplasmic ribosomal protein S11. The nucleotide sequence was determined and the derived amino acid sequence reveals that the protein has 158 amino acid residues and a calculated molecular mass of 18,424 Da. Amino acid sequence comparison with the homologous counterparts from very diverse groups of organisms representing animals (human and rat), fungi (yeast) and plants (maize and Arabidopsis thaliana), shows that this protein is very conserved during evolution. Furthermore, ribosomal protein S11 also shares a significant sequence homology to a set of related proteins: plastid ribosomal protein CS17 from different plants, Escherichia coli ribosomal protein S17 and Halobacterium marismortui ribosomal protein S14.

Cloning and characterization of the European seabass, Dicentrarchus labrax, mitochondrial genome.

Mitochondrial DNA (mtDNA) from the European seabass, Dicentrarchus labrax, has been cloned and characterized. Its gene organization was deduced by a comparison of the sequenced termini of different subclones obtained from European seabass mtDNA to the completely-sequenced mtDNAs from carp and freshwater loach. The difference in genome size between the European seabass mtDNA (approximately 18 kb) and most of the other characterized fish mtDNAs (approximately 16.5 kb) is accounted for by the displacement-loop (D-loop). Comparisons have been performed between the derived amino-acid sequences of three sequenced genes, cytochrome c oxidase subunit 2 (COII), NADH dehydrogenase subunit 4L (ND4L) and ATP synthase subunit 8 (ATPase8), from D. labrax, and their counterparts in other fishes and Xenopus laevis.

U17XS8, a small nucleolar RNA with a 12 nt complementarity to 18S rRNA and coded by a sequence repeated in the six introns of Xenopus laevis ribosomal protein S8 gene.

U17XS8 RNA is a 220 nt small RNA coded by a sequence repeated in each of the six introns of the gene for ribosomal protein S8 of Xenopus laevis. It is mainly localized in the nucleolus, as shown by in situ hybridization, and it is assembled in a ribonucleoprotein particle (RNP) sedimenting at about 12S, slightly faster than U3 RNP, and with a density of 1.45 g/ml. DNA and RNA microinjections in Xenopus oocytes have shown that U17XS8 RNA is not the product of an independent transcription unit, but is produced by processing of intron sequences of r-protein S8 transcript, as has been recently shown for other small nucleolar RNAs encoded in the introns of other genes. Its accumulation during Xenopus development, oogenesis and embryogenesis, increases in parallel to that of r-protein S8 mRNA. Another interesting feature is the presence in the U17XS8 RNA of a 12 nt sequence complementary to 18S rRNA. The results presented suggest a possible role of this RNA in some step(s) of ribosome assembling in the nucleolus. Some relevant differences between Xenopus U17XS8 RNA and the corresponding human U17 RNA, recently described, have been observed.

Human ribosomal protein L4: cloning and sequencing of the cDNA and primary structure of the protein.

The cloning and sequencing of a cDNA for human ribosomal protein L4 is reported. The corresponding mRNA has a very short 5' untranslated region initiating with a sequence of 12 pyrimidines, characteristic of all vertebrate ribosomal protein mRNAs. The deduced amino acid sequence shows that human ribosomal protein L4 has 425 amino acid residues and a calculated molecular mass of 47,821 Da. Comparison with the homologous counterparts of Xenopus, Drosophila and yeast shows that this protein has a very conserved amino-terminus region and an extremely divergent carboxyl-terminus portion.

Molecular phylogenies in Dolichopoda cave crickets and mtDNA rate calibration.

Five species of Dolichopoda cave crickets have been studied by means of mtDNA RFLPs. The phylogenetic relationships among them were previously inferred from two different molecular measures: allozyme polymorphisms and DNA-DNA hybridization. mtDNA data generate a phylogeny exactly matching those obtained from the other two genetic markers. This is not always the case for other organisms studied so far. This result is discussed in respect of the performance of the three molecular approaches and the population biology of these cave dwelling insects. A tentative calibration of mtDNA rate for Dolichopoda produces an estimate of about 2%/lineage/Myr. The comparison between mtDNA and scnDNA divergence estimates suggests that in these crickets changes accumulate approximately 2-3 times faster in mitochondrial than single copy nuclear sequences.

Sequence of the gene coding for ribosomal protein S8 of Xenopus laevis.

We present here the cloning and the entire sequence of one of the two gene copies coding for ribosomal protein (r-protein) S8 in Xenopus laevis (corresponding to r-protein S7 in rat) and its flanking regions. The S8a gene contains seven exons and six introns for a total length of about 12,700 bp coding for a mRNA of 663 nucleotides (nt) plus a poly(A) tail. Mapping of the 5' end of the gene has shown that the transcription start point is located in a pyrimidine-rich tract, as has been observed for all r-protein-encoding genes of X. laevis and other vertebrates so far characterized. A computer analysis of the S8a sequence has revealed the presence of a 220-nt sequence repeated, with some variations, once in each of the six introns. RNA analysis by hybridization with oligo probes specific for the two gene copies coding for r-protein S8 has demonstrated that the two of them are expressed at similar levels both in oocytes and in embryos.

The pyrimidine sequence encompassing the transcription start point of Xenopus laevis ribosomal-protein-encoding genes is not obligatory for activity in oocytes.

The genes coding for ribosomal proteins (r-proteins) in Xenopus laevis have a stretch of about 20 pyrimidines (Y) at their 5' end, in the middle of which is localized the main transcription start point (tsp). To obtain information about its possible functional significance, we have introduced by site-directed mutagenesis one or more purines at various positions within the oligo(Y) tract present at the 5' end of the gene coding for r-protein S19 of X. laevis. The effect of these mutations on transcription and translation of a reporter-coding sequence has been evaluated by DNA microinjection in X. laevis oocytes. We show that an uninterrupted stretch of pyrimidines is not necessary for efficient transcription and translation of the reporter gene in the X. laevis oocyte. This finding does not exclude the possibility that this sequence is involved in transcription and/or translation regulation in some developmental situations different from oogenesis.