Accurate determination of the Gibbs energy of Cu-Zr melts using the thermodynamic integration method in Monte Carlo simulations.

The design of multicomponent alloys used in different applications based on specific thermo-physical properties determined experimentally or predicted from theoretical calculations is of major importance in many engineering applications. A procedure based on Monte Carlo simulations (MCS) and the thermodynamic integration (TI) method to improve the quality of the predicted thermodynamic properties calculated from classical thermodynamic calculations is presented in this study. The Gibbs energy function of the liquid phase of the Cu-Zr system at 1800 K has been determined based on this approach. The internal structure of Cu-Zr melts and amorphous alloys at different temperatures, as well as other physical properties were also obtained from MCS in which the phase trajectory was modeled by the modified embedded atom model formalism. A rigorous comparison between available experimental data and simulated thermo-physical properties obtained from our MCS is presented in this work. The modified quasichemical model in the pair approximation was parameterized using the internal structure data obtained from our MCS and the precise Gibbs energy function calculated at 1800 K from the TI method. The predicted activity of copper in Cu-Zr melts at 1499 K obtained from our thermodynamic optimization was corroborated by experimental data found in the literature. The validity of the amplitude of the entropy of mixing obtained from the in silico procedure presented in this work was analyzed based on the thermodynamic description of hard sphere mixtures.

Illegitimate DNA integration in mammalian cells.

Foreign DNA integration is one of the most widely exploited cellular processes in molecular biology. Its technical use permits us to alter a cellular genome by incorporating a fragment of foreign DNA into the chromosomal DNA. This process employs the cell's own endogenous DNA modification and repair machinery. Two main classes of integration mechanisms exist: those that draw on sequence similarity between the foreign and genomic sequences to carry out homology-directed modifications, and the nonhomologous or 'illegitimate' insertion of foreign DNA into the genome. Gene therapy procedures can result in illegitimate integration of introduced sequences and thus pose a risk of unforeseeable genomic alterations. The choice of insertion site, the degree to which the foreign DNA and endogenous locus are modified before or during integration, and the resulting impact on structure, expression, and stability of the genome are all factors of illegitimate DNA integration that must be considered, in particular when designing genetic therapies.

RNP localization and transport in yeast.

The localization of mRNAs is used by various types of polarized cells to locally translate specific proteins, which restricts their distribution to a particular sub-region of the cytoplasm. This mechanism of protein sorting is involved in major biological processes such as asymmetric cell division, oogenesis, cellular motility, and synapse formation. With the finding of localized mRNAs in the yeast Saccharomyces cerevisiae, it is now possible to benefit from the powerful yeast laboratory tools to explore the molecular basis of RNA localization. Because mRNA transport and localization in yeast share many features with RNA localization in higher eukaryotes, including the formation of a large ribonucleoprotein (RNP) localization complex, the requirement of a polarized cytoskeleton and molecular motors, and the role of nuclear RNA-binding proteins in cytoplasmic localization, the yeast can be used as a paradigm for unraveling the molecular aspects of this process. This review summarizes the current knowledge on RNP transport and localization in yeast.

An exclusively nuclear RNA-binding protein affects asymmetric localization of ASH1 mRNA and Ash1p in yeast.

The localization of ASH1 mRNA to the distal tip of budding yeast cells is essential for the proper regulation of mating type switching in Saccharomyces cerevisiae. A localization element that is predominantly in the 3'-untranslated region (UTR) can direct this mRNA to the bud. Using this element in the three-hybrid in vivo RNA-binding assay, we identified a protein, Loc1p, that binds in vitro directly to the wild-type ASH1 3'-UTR RNA, but not to a mutant RNA incapable of localizing to the bud nor to several other mRNAs. LOC1 codes for a novel protein that recognizes double-stranded RNA structures and is required for efficient localization of ASH1 mRNA. Accordingly, Ash1p gets symmetrically distributed between daughter and mother cells in a loc1 strain. Surprisingly, Loc1p was found to be strictly nuclear, unlike other known RNA-binding proteins involved in mRNA localization which shuttle between the nucleus and the cytoplasm. We propose that efficient cytoplasmic ASH1 mRNA localization requires a previous interaction with specific nuclear factors.

She2p is a novel RNA-binding protein that recruits the Myo4p-She3p complex to ASH1 mRNA.

In Saccharomyces cerevisiae, Ash1p is a specific repressor of transcription that localizes exclusively to daughter cell nuclei through the asymmetric localization of ASH1 mRNA. This localization requires four cis-acting localization elements located in the ASH1 mRNA, five trans-acting factors, one of which is a myosin, and the actin cytoskeleton. The RNA-binding proteins that interact with these cis-elements remained to be identified. Starting with the 3' most localization element of ASH1 mRNA in the three-hybrid assay, element E3, we isolated a clone corresponding to the C-terminus of She3p. We also found that She3p and She2p interact, and this interaction is essential for the binding of She3p with element E3 in vivo. Moreover, She2p was observed to bind the E3 RNA directly in vitro and each of the ASH1 cis-acting localization elements requires She2p for their localization function. By tethering a She3p-MS2 fusion protein to a reporter RNA containing MS2 binding sites, we observed that She2p is dispensable for She3p-MS2-dependent RNA localization.

The role of nuclear cap binding protein Cbc1p of yeast in mRNA termination and degradation.

The cyc1-512 mutation in Saccharomyces cerevisiae causes a 90% reduction in the level of iso-1-cytochrome c because of the lack of a proper 3'-end-forming signal, resulting in low levels of eight aberrantly long cyc1-512 mRNAs which differ in length at their 3' termini. cyc1-512 can be suppressed by deletion of either of the nonessential genes CBC1 and CBC2, which encode the CBP80 and CBP20 subunits of the nuclear cap binding complex, respectively, or by deletion of the nonessential gene UPF1, which encodes a major component of the mRNA surveillance complex. The upf1-Delta deletion suppressed the cyc1-512 defect by diminishing degradation of the longer subset of cyc1-512 mRNAs, suggesting that downstream elements or structures occurred in the extended 3' region, similar to the downstream elements exposed by transcripts bearing premature nonsense mutations. On the other hand, suppression of cyc1-512 defects by cbc1-Delta occurred by two different mechanisms. The levels of the shorter cyc1-512 transcripts were enhanced in the cbc1-Delta mutants by promoting 3'-end formation at otherwise-weak sites, whereas the levels of the longer cyc1-512 transcripts, as well as of all mRNAs, were slightly enhanced by diminishing degradation. Furthermore, cbc1-Delta greatly suppressed the degradation of mRNAs and other phenotypes of a rat7-1 strain which is defective in mRNA export. We suggest that Cbc1p defines a novel degradation pathway that acts on mRNAs partially retained in nuclei.

The odyssey of a regulated transcript.

The transcript of the Saccharomyces cerevisiae gene, RPL30, is subject to regulated splicing and regulated translation, due to a structure that interacts with its own product, ribosomal protein L30. We have followed the fate of the regulated RPL30 transcripts in vivo. Initially, these transcripts abortively enter the splicing pathway, forming an unusually stable association with U1 snRNP. A large proportion of the unspliced molecules, however, are found in the cytoplasm. Most of these are still bound by L30, as only a small fraction are engaged in translation. Eventually, the unspliced RPL30 transcripts escape the grasp of L30, associate with ribosomes, and fall prey to nonsense mediated decay.

A double-strand break in a chromosomal LINE element can be repaired by gene conversion with various endogenous LINE elements in mouse cells.

A double-strand break (DSB) in the mammalian genome has been shown to be a very potent signal for the cell to activate repair processes. Two different types of repair have been identified in mammalian cells. Broken ends can be rejoined with or without loss or addition of DNA or, alternatively, a homologous template can be used to repair the break. For most genomic sequences the latter event would involve allelic sequences present on the sister chromatid or homologous chromosome. However, since more than 30% of our genome consists of repetitive sequences, these would have the option of using nonallelic sequences for homologous repair. This could have an impact on the evolution of these sequences and of the genome itself. We have designed an assay to look at the repair of DSBs in LINE-1 (L1) elements which number 10(5) copies distributed throughout the genome of all mammals. We introduced into the genome of mouse epithelial cells an L1 element with an I-SceI endonuclease site. We induced DSBs at the I-SceI site and determined their mechanism of repair. We found that in over 95% of cases, the DSBs were repaired by an end-joining process. However, in almost 1% of cases, we found strong evidence for repair involving gene conversion with various endogenous L1 elements, with some being used preferentially. In particular, the T(F) family and the L1Md-A2 subfamily, which are the most active in retrotransposition, appeared to be contributing the most in this process. The degree of homology did not seem to be a determining factor in the selection of the endogenous elements used for repair but may be based instead on accessibility. Considering their abundance and dispersion, gene conversion between repetitive elements may be occurring frequently enough to be playing a role in their evolution.

Structural elements required for the localization of ASH1 mRNA and of a green fluorescent protein reporter particle in vivo.

The sorting of the Ash1 protein to the daughter nucleus of Saccharomyces cerevisiae in late anaphase of the budding cycle correlates with the localization of ASH1 mRNA at the bud tip [1] [2]. Although the 3' untranslated region (3' UTR) of ASH1 is sufficient to localize a reporter mRNA, it is not necessary, a result which indicates that other sequences are involved [1]. We report the identification of three additional cis-acting elements in the coding region. Each element alone, when fused to a lacZ reporter gene, was sufficient for the localization of the lacZ mRNA reporter to the bud. A fine-structure analysis of the 3' UTR element showed that its function in mRNA localization did not depend on a specific sequence but on the secondary and tertiary structure of a minimal 118 nucleotide stem-loop. Mutations in the stem-loop that affect the localization of the lacZ mRNA reporter also affected the formation of the localization particles, in living cells, composed of a green fluorescent protein (GFP) complexed with lacZ-ASH1-3' UTR mRNA [3]. A specific stem-loop in the 3' UTR of the ASH1 mRNA is therefore required for both localization and particle formation, suggesting that complex formation is part of the localization mechanism. An analysis on one of the coding-region elements revealed a comparable stem-loop structure with similar functional requirements.

Localization of ASH1 mRNA particles in living yeast.

ASH1 mRNA localizes to the bud tip in Saccharomyces cerevisiae to establish asymmetry of HO expression, important for mating type switching. To visualize real time localization of the mRNA in living yeast cells, green fluorescent protein (GFP) was fused to the RNA-binding protein MS2 to follow a reporter mRNA containing MS2-binding sites. Formation and localization of a GFP particle in the bud required ASH1 3'UTR (untranslated region) sequences. The SHE mutants disrupt RNA and particle localization and SHE 2 and 3 mutants inhibit particle formation as well. Both She3myc and She1myc colocalized with the particle. Video microscopy demonstrated that She1p/Myo4p moved particles to the bud tip at 200-440 nm/sec. Therefore, the ASH1 3'UTR-dependent particle serves as a marker for RNA transport and localization.

Modeling active RNA structures using the intersection of conformational space: application to the lead-activated ribozyme.

The Pb2+ cleavage of a specific phosphodiester bond in yeast tRNA(Phe) is the classical model of metal-assisted RNA catalysis. In vitro selection experiments have identified a tRNA(Phe) variant, the leadzyme, that is very active in cleavage by Pb2+. We present here a three-dimensional modeling protocol that was used to propose a structure for this ribozyme, and is based on the computation of the intersection of conformational space of sequence variants and the use of chemical modification data. Sequence and secondary structure data were used in a first round of computer modeling that allowed identification of conformations compatible with all known leadzyme variants. Common conformations were then tested experimentally by evaluating the activity of analogues containing modified nucleotides in the catalytic core. These experiments led to a new structural hypothesis that was tested in a second round of computer modeling. The resulting proposal for the active conformation of the leadzyme is consistent with all known structural data. The final model suggests an in-line SN2 attack mechanism and predicts two Pb2+ binding sites. The protocol presented here is generally applicable in modeling RNAs whenever the catalytic or binding activity of structural analogues is known.

Direct evidence that transgene integration is random in murine cells, implying that naturally occurring double-strand breaks may be distributed similarly within the genome.

We have examined the distribution of illegitimate integration of a transgene within the genome of cells of a murine fibroblast cell line, LTA, using fluorescence in situ hybridization (FISH) analysis. The transgene vector contained specific sequences for detection via FISH and a hygromycin resistance gene for selection. Cells were transfected via CaPO4, and pools of 250 to 3000 hygromycin-resistant clones were subjected to FISH analysis. The integration of the transgene was scored for chromosome morphology (acrocentric, metacentric or dicentric) and position (relative to centromere or telomere). More than 90% of the hygromycin-resistant clones observed involved integration of the transgene singly or as multiple copies, at a single site within the genome. No bias was observed for integration of the transgene in any particular chromosome morphology or chromosomal position, even in the presence, within the genome, of sequences homologous to the transgene. This study presents direct evidence that illegitimate integration of a transgene occurs randomly in murine fibroblasts. Since it is postulated that initiation of illegitimate recombination involves a double-strand break (DSB), a corollary to the above results would be that naturally occurring DSBs also occur randomly within the murine genome.

The processing of DNA ends at double-strand breaks during homologous recombination: different roles for the two ends.

We have investigated the role of DNA ends during gap repair by homologous recombination. Mouse cells were transfected with a gapped plasmid carrying distinctive ends: on one side mouse LINE-1 repetitive sequences (L1Md-A2), and on the other rat LINE-1 sequences (L1Rn-3). The gap could be repaired by homologous recombination with endogenous mouse genomic LINE-1 elements, which are on average 95% and 85% homologous to L1Md-A2 and L1Rn-3 ends, respectively. Both L1Md-A2 and L1Rn-3 ends were found to initiate gap repair with equal efficiency. However, there were two types of gap repair products--precise and imprecise--the occurrence of which appears to depend on which end had been used for initiation and thus which end was left available for subsequent steps in recombination. These results, together with sequence analysis of recombinants obtained with plasmids having either mouse or rat LINE-1 sequences flanking the gap, strongly suggest that the two DNA ends played different roles in recombinational gap repair. One end was used to initiate the gap repair process, while the other end was involved at later steps, in the resolution of the recombination event.

Ectopic gene targeting exhibits a bimodal distribution of integration in murine cells, indicating that both intra- and interchromosomal sites are accessible to the targeting vector.

Ectopic gene targeting is an alternative outcome of the gene targeting process in which the targeting vector acquires sequences from the genomic target but proceeds to integrate elsewhere in the genome. Using two-color fluorescent in situ hybridization analysis, we have determined the integration sites of the gene targeting vector with respect to the target locus in a murine fibroblast line (LTA). We found that for ectopic gene targeting the distribution of integration sites was bimodal, being either within 3 Mb of the target or on chromosomes distinct from the chromosome carrying the target locus. Inter- and intrachromosomal sites appeared to be equally accessible to the targeting vector, with site-specific variations. Interestingly, interphase analysis indicated that vector sequences which had integrated ectopically in chromosomes other than the target colocalized with the target locus at a significant frequency compared to that of colocalization to random unlinked loci. We propose that ectopic gene targeting could be used to determine which chromosomal domains within the genome are accessible to a given genetic locus. Thus, recombination access mapping may present a new paradigm for the analysis of DNA accessibility and interaction within the genome.

Effect of structural modifications on the activity of the leadzyme.

The structure/function properties of functional groups in the leadzyme have been studied by assaying the activity of analog ribozymes generated by the systematic substitution of modified nucleotides in the internal loop region of the ribozyme. Guanosine analogs introduced at positions 4 and 7 occupied by guanosine in the wild-type molecule severely diminished cleavage. The substitution of deoxycytidine for cytidine at the cleavage site completely eliminated the activity of the leadzyme, as expected if the adjacent 2'-OH were the nucleophile in the cleavage reaction. On the other hand, substitution of an abasic nucleotide for adenosine at position 8 did not affect the activity of the ribozyme. An analysis of the activity of these analogs gives rise to the proposal of a triple-base pair motif implicating C1, G4, and G7.

Homologous junctions formed between a vector and human genomic repetitive LINE-1 elements as a result of one-sided invasion.

Studies on homologous recombination in mammalian cells between an exogenous DNA molecule containing a double-strand break and a homologous genomic sequence have indicated that there were at least two distinct types of homologous recombination processes, one that involved the formation of two homologous junctions and another that involved the formation of one homologous junction and one illegitimate junction. Both types of events are produced in gene targeting experiments. We have proposed a model to account for the later process called one-sided invasion. One-sided invasion has now been reported in numerous species belonging to different phyla and appears to be a universal mechanism. It has also been observed in normal human germ cells. The role of one-sided invasion is still unknown. Using a recombination assay between LINE-1 elements from the human genome and exogenous LINE-1 sequences, we have characterized the process of homologous junction formation in one-sided invasion. We found that at each of the homologous junctions, variable lengths of the vector L1 sequences had been replaced by genomic L1 sequences. We also found a homologous junction that involved three partners, suggesting that the homologous end could be released and become available for a second round of interaction.

Human monoclonal Fab fragments recovered from a combinatorial library bind specifically to the platelet HPA-1a alloantigen on glycoprotein IIb-IIIa.

BACKGROUND AND OBJECTIVES: Certain clinical conditions are related to the presence of platelet-specific alloantibodies in the patient's serum. We studied the molecular diversity of HPA-1a antibodies to analyze some peculiarities of this antibody response. MATERIALS AND METHODS: Human antibody Fab fragments that bind to the platelet alloantigen HPA-1a on glycoprotein IIb-IIIa (GPIIbIIIa) were generated by using a recombinant phage display system. We established an immunoglobulin G1, kappa combinatorial library from the peripheral blood lymphocytes of a person undergoing a severe posttransfusion purpura. RESULTS: Characterization of Fab clones selected from the fifth round of antigen-specific panning of this library demonstrates a highly specific reactivity to the HPA-1a alloantigen. The nucleotide sequence analysis of representative HPA-la-specific clones reveals at least 3 distinct V1 and 3VH gene segments that present an extensive degree of mutation as demonstrated by comparison of gene usage and homologies to the nearest germline genes. CONCLUSIONS: These human HPA-la-specific Fab reagents should allow us to better understand the molecular mechanism involved in HPA-la alloimmunization.

Differential behavior of curved DNA upon untwisting.

We have synthesized DNA segments with different handedness, twisting and radii of curvature, and have analyzed the effect of untwisting on them. The results indicate that the dynamic behavior of curved DNA upon untwisting is strongly determined by the initial sequence-dependent DNA trajectory. In particular, DNA with the same radii but with opposite handedness of superhelix twisting can show very different conformational responses to ethidium bromide untwisting. Upon treatment with ethidium bromide, right-handed superhelixes decrease their twist and increase the planarity of the superhelix, while left-handed superhelixes increase twisting and decrease their degree of planarity.