Wine and tumors: study of resveratrol.

In modern industrial societies the attention to public health, especially in relation to food habits, is increasing day by day. Considering this, it's no wonder that wine, the voluptuary drink that best represents human history, is the most interesting compound. The main and best known wine effects on the human body are caused by alcohol, but several other active compounds are present in wine. Above all, resveratrol is able to neutralize free radicals, which can damage DNA and may lead to cancer onset. In this study, we have indagated resveratrol anticancer action, analyzing its effects on both cell cycle and growing of human lymphoma B (DHL-4) cells. MTT colorimetric test, tripan blue dye exclusion assay, and cell cycle analysis showed that resveratrol has a dose-dependent antiproliferative and antiapoptotic action on DHL-4 cells. These results confirm resveratrol's potential therapeutic role on tumors.

Two RNA-binding domains determine the RNA-binding specificity of nucleolin.

Nucleolin is an abundant nucleolar RNA-binding protein that seems to be involved in many aspects of ribosome biogenesis. Nucleolin contains four copies of a consensus RNA-binding domain (CS-RBD) found in several other proteins. In vitro RNA-binding studies previously determined that nucleolin interacts specifically with a short RNA stem-loop structure. Taken individually, none of the four CS-RBDs interacts significantly with the RNA target, but a peptide that contains the first two adjacent CS-RBDs (R12) is sufficient to account for nucleolin RNA-binding specificity and affinity. The full integrity of these two domains is required, since N- or C-terminal deletion abolishes the specific interaction with the RNA. Mutation of conserved amino acids within the RNP-1 sequence of CS-RBD 1 or 2 drastically reduces the interaction with the RNA, whereas mutation of the analogous residues in CS-RBDs 3 and 4 has no effect in the context of the R1234G protein (which corresponds to the C-terminal end of nucleolin). Our results demonstrate that nucleolin RNA-binding specificity is the result of a cooperation between two CS-RBDs (RBDs 1 and 2) and also suggests a direct or indirect involvement of the RNP-1 consensus sequence of both CS-RBDs in the recognition of the RNA target.

Localization of nucleolin binding sites on human and mouse pre-ribosomal RNA.

Nucleolin, a major RNA binding protein of the nucleolus is found associated mainly to the pre-ribosomal particles and is absent from the cytoplasmic mature ribosomes. The role of this protein in ribosome biogenesis remains largely unknown, and is likely to be reflected by its RNA binding properties. Nucleolin contains in its central domain four RNA recognition motifs (RRM, also called RBD for RNA binding domain) which are conserved among different species. RNA binding studies have revealed that nucleolin interacts specifically with a short stem loop structure called NRE (nucleolin recognition element). We show that nucleolin extracted from human, hamster and mouse cells interacts with the same specificity and affinity to a mouse 5'ETS (external transcribed spacer) RNA fragment which contains a NRE motif. A similar structure within the human 5'ETS is also efficiently recognized by mouse nucleolin. We identified putative NRE not only in the 5'ETS but also in the 3'ETS, ITS (internal transcribed spacer) and in the 18S and 28S RNA sequences. This is in agreement with in vivo cross-linking data and a previous immunocytological analysis of ribosomal transcription units. Interestingly, we found that all the NRE localized in the 28S region are within the variable domains. Despite considerable sequence divergence of these domains, several of the NRE have sequences perfectly conserved between these two species. This suggests that these nucleolin binding sites might be functionally important, in particular for ribosome biogenesis.

Concerted activities of the RNA recognition and the glycine-rich C-terminal domains of nucleolin are required for efficient complex formation with pre-ribosomal RNA.

Nucleolin is an abundant nucleolar protein which is involved in the early stages of ribosome assembly. The central 40-kDa domain of nucleolin comprises four RNA recognition motifs (RRM) which are presumed to be involved in specific interactions with pre-rRNA. In order to examine in detail the role of this central domain and the contribution of the N-terminal and C-terminal domains of nucleolin to RNA binding, we have used an Escherichia coli expression system to synthezise polypeptides corresponding to various combinations of the three domains and their subdomains. By means of an in-vitro binding assay and a synthetic RNA corresponding to a specific recognition site in pre-rRNA we have been able to demonstrate conclusively that the central 40-kDa domain is indeed responsible for the specificity of RNA recognition and that the N-terminal domain can be removed without affecting RNA binding. Most interestingly, it appears that the C-terminal 10-kDa domain, which is rich in glycine and arginine residues, is essential for efficient binding of nucleolin to RNA, but does not itself contribute to the specificity of the interaction. Circular dichroic spectroscopic probing of the RNA component shows that the C-terminal domain significantly modifies the RNA-binding properties of the central RRM core. Finally, infrared spectroscopic studies reveal that the central 40-kDa domain is structured in alpha helices and beta sheets and that the interaction with the specific pre-rRNA site induces subtle changes in the beta sheet conformation.

The glycine-rich domain of nucleolin has an unusual supersecondary structure responsible for its RNA-helix-destabilizing properties.

Nucleolin, a major nucleolar protein implicated in preribosome assembly and transcriptional regulation, possesses a C-terminal domain unusually rich in glycine, arginine, and phenylalanine residues. A polypeptide (p10), corresponding to this domain, has been synthesized by means of an Escherichia coli expression system and purified to homogeneity. Nitrocellulose binding assays have clearly shown that this domain of nucleolin is capable of interacting with RNA, and indeed all nucleic acids tested, in an efficient but nonspecific manner. A combination of circular dichroism and infrared spectroscopy provide strong evidence that repeated beta-turns are a major structural component of this polypeptide, which is entirely consistent with its amino acid composition and above all the presence of repeat motifs such as RGGF. Circular dichroism technique also shows that the interaction of p10 with RNA involves an unstacking of the nucleotide bases and an unfolding of the RNA secondary structure. While the role of the C-terminal domain of nucleolin in vivo has yet to be established, our findings suggest that it may act to unfold regions of ribosomal RNA so that a second domain of nucleolin has access to its specific binding site.