Intrinsic disorder in protein sense‐antisense recognition

In addition to the well‐established sense‐antisense complementarity abundantly present in the nucleic acid world and serving as a basic principle of the specific double‐helical structure of DNA, production of mRNA, and genetic code‐based biosynthesis of proteins, sense‐antisense complementarity is also present in proteins, where sense and antisense peptides were shown to interact with each other with increased probability. In nucleic acids, sense‐antisense complementarity is achieved via the Watson‐Crick complementarity of the base pairs or nucleotide pairing. In proteins, the complementarity between sense and antisense peptides depends on a specific hydropathic pattern, where codons for hydrophilic and hydrophobic amino acids in a sense peptide are complemented by the codons for hydrophobic and hydrophilic amino acids in its antisense counterpart. We are showing here that in addition to this pattern of the complementary hydrophobicity, sense and antisense peptides are characterized by the complementary order‐disorder patterns and show complementarity in sequence distribution of their disorder‐based interaction sites. We also discuss how this order‐disorder complementarity can be related to protein evolution.     

Antisense downregulation of SARS-CoV gene expression in Vero E6 cells

BACKGROUND: Severe acute respiratory syndrome (SARS) is caused by a novel coronavirus (SARS-CoV). It is an enveloped, single-stranded, plus-sense RNA virus with a genome of approximately 30 kb. The structural proteins E, M and N of SARS-CoV play important roles during host cell entry and viral morphogenesis and release. Therefore, we have studied whether expression of these structural proteins can be down-regulated using an antisense technique. METHODS: Vero E6 cells were transfected with plasmid constructs containing exons of the SARS-CoV structural protein E, M or N genes or their exons in frame with the reporter protein EGFP. The transfected cell cultures were treated with antisense phosphorothioated oligonucleotides (antisense PS-ODN, 20mer) or a control oligonucleotide by addition to the culture medium. RESULTS: Among a total of 26 antisense PS-ODNs targeting E, M and N genes, we obtained six antisense PS-ODNs which could sequence-specifically reduce target genes expression by over 90% at the concentration of 50 microM in the cell culture medium tested by RT-PCR. The antisense effect was further proved by down-regulating the expression of the fusion proteins containing the structural proteins E, M or N in frame with the reporter protein EGFP. In Vero E6 cells, the antisense effect was dependent on the concentrations of the antisense PS-ODNs in a range of 0-10 microM or 0-30 microM. CONCLUSIONS: The antisense PS-ODNs are effective in downregulation of SARS. The findings indicate that antisense knockdown of SARS could be a useful strategy for treatment of SARS, and could also be suitable for studies of the pathological function of SARS genes in a cellular model system.     

Interaction of antisense DNA with nucleic acids/proteins.

In order to study interaction of various types of labeled antisense DNAs were prepared. Fluorescein and 2,2,6,6-tetramethypiperidine-N-oxyl were the label molecules, which were introduced to 5'-end of oligonucleotides and their analogs. Interactions of labeled antisense DNAs with nucleic acids or proteins such as HSA, HIG and TF, were studied by UV, fluorescence depolarization spectroscopy, and ESR spectroscopy. Hybrid formation of antisense DNAs with oligonucleotides in solution could be monitored by the increase in fluorescence anisotropy (r) and by intensity change in ESR spectra. When phosphorothioate type antisense molecules anchoring fluorescein (F-OPT) were mixed with proteins, r drastically increased, whereas ODN slightly increased. These results suggest that OPTs have much more affinity for proteins than ODNs.     

Antisense inhibition of the photosynthetic antenna proteins CP29 and CP26: implications for the mechanism of protective energy dissipation

The specific roles of the chlorophyll a/b binding proteins CP29 and CP26 in light harvesting and energy dissipation within the photosynthetic apparatus have been investigated. Arabidopsis was transformed with antisense constructs against the genes encoding the CP29 or CP26 apoprotein, which gave rise to several transgenic lines with remarkably low amounts of the antisense target proteins. The decrease in the level of CP24 protein in the CP29 antisense lines indicates a physical interaction between these complexes. Analysis of chlorophyll fluorescence showed that removal of the proteins affected photosystem II function, probably as a result of changes in the organization of the light-harvesting antenna. However, whole plant measurements showed that overall photosynthetic rates were similar to those in the wild type. Both antisense lines were capable of the qE type of nonphotochemical fluorescence quenching, although there were minor changes in the capacity for quenching and in its induction kinetics. High-light-induced violaxanthin deepoxidation to zeaxanthin was not affected, although the pool size of these pigments was decreased slightly. We conclude that CP29 and CP26 are unlikely to be sites for nonphotochemical quenching.     

Cellular proteins prevent antisense phosphorothioate oligonucleotide (SdT18) to target sense RNA (rA18): development of a new in vitro assay

There are numerous indications that the "antisense" mechanism alone cannot account for the observed effects in living cells. Despite that, interactions between antisense oligonucleotides (ASO) and cellular proteins are usually not considered. In this work, we have tested the ability of antisense phosphorothioate (SdT) oligonucleotides and natural deoxyoligonucleotides (dT) for their ability to interact with target RNA in the presence of cellular proteins. We show that the affinity for cellular proteins is an essential factor that determines the success of RNA targeting. We have used a simple nuclease digestion assay to detect RNA/ASO hybrid formation in the presence of proteins. The results show the inability of a phosphorothioate oligonucleotide (SdT18) to reach the target RNA (rA18) in vitro in the presence of proteins. However, if proteins are absent, the RNA targeting was successful, as is usual in in vitro assays. Note that the target RNA concentration exceeded physiological values by several orders of magnitude while the crude protein extract was 20-fold diluted in the reaction tube. This finding is compatible with the notion that therapeutic properties of phosphorothioates could largely derive from a so-called "aptamer" effect.     

A possible origin of newly-born bacterial genes: significance of GC-rich nonstop frame on antisense strand.

Base compositions were examined at every position in codons of more than 50 genes from taxonomically different bacteria and of the corresponding antisense sequences on the bacterial genes. We propose that the nonstop frame on antisense strand [NSF(a)] of GC-rich bacterial genes is the most promising sequence for newly-born genes. Reasons are: (i) NSF(a) frequently appears on the antisense strand of GC-rich bacterial genes; (ii) base compositions at three positions in the codon are nearly symmetrical between the gene having around 55% GC content and the corresponding NSF(a); (iii) amino acid compositions of actual proteins are also similar to those of hypothetical proteins from the GC-rich NSF(a); and (iv) proteins from NSF(a) of 60% or more GC content are flexible enough to adapt to various molecules encountered as novel substrates, due to the high glycine content. To support our proposition, using a computer we generated hypothetical antisense sequences with the same base compositions as of NSF(a) at each base position in the codon, and examined properties of resulting proteins encoded by the imaginary genes. It was confirmed that NSF(a) of GC-rich gene carrying about 60% GC content is competent enough for a newly-born gene.     

Two genetic codes, one genome: frameshifted primate mitochondrial genes code for additional proteins in presence of antisense antitermination tRNAs

Genomic amino acid usages coevolve with cloverleaf formation capacities of corresponding primate mitochondrial tRNAs, also for antisense tRNAs, suggesting translational function for sense and antisense tRNAs. Some antisense tRNAs are antitermination tRNAs (anticodons match stops (UAR: UAA, UAG; AGR: AGA, AGG)). Genomes possessing antitermination tRNAs avoid corresponding stops in frames 0 and +1, preventing translational antitermination. In frame +2, AGR stop frequencies and corresponding antisense antitermination tRNAs coevolve positively. This suggests expression of frameshifted overlapping genes, potentially shortening genomes, increasing metabolic efficiency. Blast analyses of hypothetical proteins translated from one and seven +1, respectively, +2 frameshifted human mitochondrial protein coding genes align with eleven GenBank sequences (31% of the mitochondrial coding regions). These putative overlap genes contain few UARs, AGRs align with arginine. Overlap gene numbers increase in presence of, and with time since evolution of antitermination tRNA AGR in 57 primate mitochondrial genomes. Numbers of putative proteins translated from antisense protein coding sequences and detected by blast also coevolve positively with antitermination tRNAs; expression of two of these ‘antisense’ mRNAs increases under low resource availability. Although more direct evidence is still lacking for the existence of proteins translated from overlapping mitochondrial genes and for antisense tRNAs activity, coevolutions between predicted overlap genes and the antitermination tRNAs required to translate them suggest expression of overlapping genes by an overlapping genetic code. Functions of overlapping genes remain unknown, perhaps originating from dual lifestyles of ancestral free living-parasitic mitochondria. Their amino acid composition suggests expression under anaerobic conditions.     

Do “antisense proteins” exist?

A DNA double helix consists of two complementary strands antiparallel with each other. One of them is the sense chain, while the other is an antisense chain which does not directly involve the protein-encoding process. The reason that an antisense chain cannot encode for a protein is generally attributed to the lack of certain preconditions such as a promotor and some necessary sequence segments. Suppose it were provided with all these preconditions, could an antisense chain encode for an antisense protein? To answer this question, an analysis has been performed based on the existing database. Nine proteins have been found that have a 100% sequence match with the hypothetical antisense proteins derived from the knownEscherichia coli antisense chains.On sabbatical leave from Department of Physics, Tianjin University, Tianjin, China.     

Immune Screening Identifies Novel T Cell Targets Encoded by Antisense Reading Frames of HIV-1

Cytotoxic-T lymphocyte (CTL) responses to epitopes in alternative HIV reading frames have been reported. However, the extent of CTL responses to putative proteins encoded in antisense reading frames is unknown. Using sequence alignments and computational approaches, we here predict five potential antisense HIV proteins and characterize common CTL responses against them. Results suggest that antisense-derived sequences are commonly transcribed and translated and could encode functional proteins that contain important targets of anti-HIV cellular immunity.     

Stimulatory effect of an indirectly attached RNA helicase-recruiting sequence on the suppression of gene expression by antisense oligonucleotides

Antisense oligonucleotides (ODNs) are powerful tools with which to determine the consequences of the reduced expression of a selected target gene, and they may have important therapeutic applications. Methods for predicting optimum antisense sites are not always effective because various factors, such as RNA-binding proteins, influence the secondary and tertiary structures of RNAs in vivo. To overcome this obstacle, we have attempted to engineer an antisense system that can unravel secondary and tertiary RNA structures. To create such an antisense system, we connected the constitutive transport element (CTE), an RNA motif that has the ability to interact with intracellular RNA helicases, to an antisense sequence so that helicase-binding hybrid antisense ODN would be produced in cells. We postulated that this modification would enhance antisense activity in vivo, with more frequent hybridization of the antisense ODN with its targeting site. Western blotting analysis demonstrated that a hybrid antisense ODN targeted to the bcl-2 gene suppressed the expression of this gene more effectively than did the antisense ODN alone. Our results suggest that the effects of antisense ODNs can be enhanced when their actions are combined with those of RNA helicases.     

Efficient Down-Regulation of the Major Vegetative Storage Protein Genes in Transgenic Soybean Does Not Compromise Plant Productivity

Soybean (Glycine max L. Merr.) contains two related and abundant proteins, VSP alpha and VSP beta, that have been called vegetative storage proteins (VSP) based on their pattern of accumulation, degradation, tissue localization, and other characteristics. To determine whether these proteins play a critical role in sequestering N and other nutrients during early plant development, a VspA antisense gene construct was used to create transgenic plants in which VSP expression was suppressed in leaves, flowers, and seed pods. Total VSP was reduced at least 50-fold due to a 100-fold reduction in VSP alpha and a 10-fold reduction in VSP beta. Transgenic lines were grown in replicated yield trials in the field in Nebraska during the summer of 1999 and seed harvested from the lines was analyzed for yield, protein, oil, and amino acid composition. No significant difference (alpha = 0.05) was found between down-regulated lines and controls for any of the traits tested. Young leaves of antisense plants grown in the greenhouse contained around 3% less soluble leaf protein than controls at the time of flowering. However, total leaf N did not vary. Withdrawing N from plants during seed fill did not alter final seed protein content of antisense lines compared with controls. These results indicate that the VSPs play little if any direct role in overall plant productivity under typical growth conditions. The lack of VSPs in antisense plants might be partially compensated for by increases in other proteins and/or non-protein N. The results also suggest that the VSPs could be genetically engineered or replaced without deleterious effects.     

Functional analysis of the two Arabidopsis homologues of Toc34, a component of the chloroplast protein import apparatus

Two Arabidopsis Toc34 homologues, atToc34 and atToc33, components of the chloroplast protein import machinery located in the outer envelope membrane, were recently isolated. Both proteins insert into the outer envelope, are supposed to bind GTP and to interact with Toc75 as demonstrated by in vitro import assays. We studied the expression of the two genes by RNA gel blot analysis, promoter-GUS plants and in situ hybridisations as well as immunoblot analysis. The atToc34 and atToc33 genes are expressed in green as well as non-green tissues and are developmentally regulated. Despite these similarities, however, the two Arabidopsis Toc34 homologues are differentially expressed in various plant organs. To gain more insight into the in vivo function of both proteins, antisense plants were created. While antisense plants of atToc33 are characterized by a pale yellowish phenotype, antisense plants of atToc34 show a weaker phenotype. Protein interaction studies using an in vitro translated precursor protein and heterologously expressed atToc34 and atToc33 proteins showed a direct GTP-dependent interaction, but demonstrated different affinities of the two atToc proteins towards the precursor protein. Thus, our results indicate a more specialized function for both atToc34 and atToc33, suggesting specificity for certain imported precursor proteins.     

反义肽及其在生化分离中的应用

反义肽是由反义RNA编码和翻译的肽．它可与其正义肽分子发生专一性相互作用．近年反义肽的这种特异性结合实例研究,已为其在生化分离领域应用奠定了基础,尤其是在色谱亲和配基的选择方面,可以预见不久以反义肽为配基的亲和色谱将是生物工程产品分离的一种有效手段．     

Inhibition of superoxide production in B lymphocytes by rac antisense oligonucleotides.

Rac1 and Rac2 gene products are small GTP-binding proteins showing 92% homology to each other. According to recent studies performed in cell-free systems, Rac1 and Rac2 proteins may be involved in the activation of NADPH-oxidase, the superoxide-generating enzymatic complex active in phagocytes. Epstein-Barr virus (EBV) transformed B lymphocytes, which express rac1 and rac2 genes, also efficiently release superoxide anions when triggered by various cell surface stimuli. To investigate the regulatory role of Rac proteins in living cells, we analyzed superoxide production in response to cross-linking of surface immunoglobulins or phorbol ester treatment in human EBV-transformed B lymphocytes pretreated with Rac sense and antisense oligonucleotides. We report here that (i) the rac protein content estimated by immunoblotting can be decreased by 60% in Rac antisense pretreated cells and (ii) a strong (50-60%), dose-dependent inhibition of superoxide production is observed in antisense pretreated cells whereas cells pretreated with sense oligonucleotide are unaffected. The data presented show, for the first time in whole cells, that superoxide production is modulated by the Rac protein content, thus demonstrating the physiological role of Rac proteins in the regulation of NADPH-oxidase.