Silvano Riva

A novel procedure for quantitative polymerase chain reaction by coamplification of competitive templates

A method is described for the absolute quantification by polymerase chain reaction (PCR) of nucleic acids present in low abundance. The method entails the addition to the sample of competitor DNA molecules that share the same sequence as the amplified target (including primer recognition sites), except for a 20-bp insertion in the middle, which allows easy resolution by gel electrophoresis (competitive PCR). Among the advantages of competitive PCR is that any predictable or unpredictable variable that affects amplification has the same effect on both target and competitor species and that the final ratio of amplified products reflects exactly the initial rate of targets, rendering the reaction independent of the number of amplification cycles. An easy and reliable method for the construction and quantification of competitive templates obtained as recombinant PCR products was developed. The technique was used for the absolute quantification of human genomic DNA with primers from a single copy, subtelomeric region of chromosome 19.

Transcription of Satellite III non-coding RNAs is a general stress response in human cells

In heat-shocked human cells, heat shock factor 1 activates transcription of tandem arrays of repetitive Satellite III (SatIII) DNA in pericentromeric heterochromatin. Satellite III RNAs remain associated with sites of transcription in nuclear stress bodies (nSBs). Here we use real-time RT-PCR to study the expression of these genomic regions. Transcription is highly asymmetrical and most of the transcripts contain the G-rich strand of the repeat. A low level of G-rich RNAs is detectable in unstressed cells and a 104-fold induction occurs after heat shock. G-rich RNAs are induced by a wide range of stress treatments including heavy metals, UV-C, oxidative and hyper-osmotic stress. Differences exist among stressing agents both for the kinetics and the extent of induction (>100- to 80.000-fold). In all cases, G-rich transcripts are associated with nSBs. On the contrary, C-rich transcripts are almost undetectable in unstressed cells and modestly increase after stress. Production of SatIII RNAs after hyper-osmotic stress depends on the Tonicity Element Binding Protein indicating that activation of the arrays is triggered by different transcription factors. This is the first example of a non-coding RNA whose transcription is controlled by different transcription factors under different growth conditions.

Modular Structure of the Human Lamin B2 Replicator

ABSTRACT The cis-acting elements necessary for the activity of DNA replication origins in metazoan cells are still poorly understood. Here we report a thorough characterization of the DNA sequence requirements of the origin associated with the human lamin B2 gene. A 1.2-kb DNA segment, comprising the start site of DNA replication and located within a large protein-bound region, as well as a CpG island, displays origin activity when moved to different ectopic positions. Genomic footprinting analysis of both the endogenous and the ectopic origins indicates that the large protein complex is assembled in both cases around the replication start site. Replacement of this footprinted region with an unrelated sequence, maintaining the CpG island intact, abolishes origin activity and the interaction with hORC2, a subunit of the origin recognition complex. Conversely, the replacement of 17 bp within the protected region reduces the extension of the protection without affecting the interaction with hORC2. This substitution does not abolish the origin activity but makes it more sensitive to the integration site. Finally, the nearby CpG island positively affects the efficiency of initiation. This analysis reveals the modular structure of the lamin B2 origin and supports the idea that sequence elements close to the replication start site play an important role in origin activation.

Early mitotic degradation of the homeoprotein HOXC10 is potentially linked to cell cycle progression

Hox proteins are transcription factors involved in controlling axial patterning, leukaemias and hereditary malformations. Here, we show that HOXC10 oscillates in abundance during the cell cycle, being targeted for degradation early in mitosis by the ubiquitin‐dependent proteasome pathway. Among abdominal‐B subfamily members, the mitotic proteolysis of HOXC10 appears unique, since the levels of the paralogous HOXD10 and the related homeoprotein HOXC13 are constant throughout the cell cycle. When two destruction box motifs (D‐box) are mutated, HOXC10 is stabilized and cells accumulate in metaphase. HOXC10 appears to be a new prometaphase target of the anaphase‐promoting complex (APC), since its degradation coincides with cyclin A destruction and is suppressed by expression of a dominant‐negative form of UbcH10, an APC‐associated ubiquitin‐conjugating enzyme. Moreover, HOXC10 co‐immunoprecipitates the APC subunit CDC27, and its in vitro degradation is reduced in APC‐depleted extracts or by competition with the APC substrate cyclin A. These data imply that HOXC10 is a homeoprotein with the potential to influence mitotic progression, and might provide a link between developmental regulation and cell cycle control.

Localization of proteins bound to a replication origin of human DNA along the cell cycle

The proteins bound in vivo at the human lamin B2 DNA replication origin and their precise sites of binding were investigated along the cell cycle utilizing two novel procedures based on immunoprecipitation following UV irradiation with a pulsed laser light source. In G1, the pre‐replicative complex contains CDC6, MCM3, ORC1 and ORC2 proteins; of these, the post‐replicative complex in S phase contains only ORC2; in M phase none of them are bound. The precise nucleotide of binding was identified for the two ORC and the CDC6 proteins near the start sites for leading‐strand synthesis; the transition from the pre‐ to the post‐replicative complex is accompanied by a 17 bp displacement of the ORC2 protein towards the start site.

A new phage of Bacillus subtilis with infectious DNA having separable strands

A new phage (SPP1) active on Bacillus subtilis has been isolated. The DNA extracted from the phage is infectious on competent cells of B. subtilis and shows the highest efficiency of infection so far observed for B. subtilis phage DNA, namely 5 to 6 × 10 3 phage equivalents per plaque-forming unit. The phage genome can be extracted as a single DNA molecule having a molecular weight of 2·5 × 10 7 . The molecular weight of phage DNA after denaturation is approximately 1·3 × 10 7 , thus demonstrating the absence of single-strand breaks. The buoyant density of SPP1 DNA in a neutral CsCl density-gradient is 1·703 g cm −3 ; denatured DNA has a bimodal density distribution at neutral pH, the two bands corresponding to the separated strands; their densities are 1·713 g cm −3 and 1·725 g cm −3 , respectively. The interaction of ribosomal RNA with the heavy strand strongly enhances its density and allows a large-scale preparation of the two separated strands. The isolated strands can be reannealed, yielding a good recovery of infectious activity.

Mammalian single-stranded DNA binding protein UP I is derived from the hnRNP core protein A1.

Antibodies induced against mammalian single‐stranded DNA binding protein (ssDBP) UP I were shown to be cross‐reactive with most of the basic hnRNP core proteins, the main constituents of 40S hnRNP particles. This suggested a structural relationship between both groups of proteins. Using the anti‐ssDBP antibodies, a cDNA clone (pRP10) was isolated from a human liver cDNA library in plasmid expression vector pEX1. By DNA sequencing this clone was shown to encode in its 949 bp insert the last 72 carboxy terminal amino acids of the ssDBP UP I. Thereafter, an open reading frame continued for another 124 amino acids followed by a UAA (ochre) stop codon. Direct amino acid sequencing of a V8 protease peptide from hnRNP core protein A1 showed that this peptide contained at its amino terminus the last 11 amino acids of UP I followed by 19 amino acids which are encoded by the open reading frame of cDNA clone pRP10 immediately following the UP I sequence. This proves that ssDBP UP I arises by proteolysis from hnRNP core protein A1. This finding must lead to a re‐evaluation of the possible physiological role of UP I and related ssDBPs. The formerly assumed function in DNA replication, although not completely ruled out, should be reconsidered in the light of a possible alternative or complementary function in hnRNA processing where UP I could either be a simple degradation product of core protein A1 (as a consequence of controlling the levels of active A1) or may continue to function as an RNA binding protein which has lost the ability to interact with the other core proteins.(ABSTRACT TRUNCATED AT 250 WORDS)

New insights into the auxiliary domains of eukaryotic RNA binding proteins

Eukaryotic RNA binding proteins (RBP) are key players in RNA processing and in post‐transcriptional regulation of gene expression. By interacting with RNA and other factors and by modulating the RNA structure, they promote the assembly of a great variety of specific ribonucleoprotein complexes. Many RBPs are composed of highly structured and conserved RNA binding domains (RBD) linked to unstructured and divergent auxiliary domains; such modular structure can account for a multiplicity of interactions. In this context, the auxiliary domains emerge as essential partners of the RBDs in both RNA binding and functional specialisation. Moreover, the determinants of biologically important functions, such as strand annealing, protein‐protein interactions, nuclear localization and activity in in vitro splicing, seem to reside in the auxiliary domains. The structural and functional properties of these domains suggest their possible derivation from ancestral non‐specific RNA binding polypeptides.

Cell cycle modulation of protein–DNA interactions at a human replication origin

We followed the variations of protein–DNA interactions occurring in vivo over the early firing replication origin located near the human lamin B2 gene, in IMR‐90 cells synchronized in different moments of the cell cycle. In G0 phase cells no protection is present; as the cells progress in G1 phase an extended footprint covering over 100 bp appears, particularly marked at the G1/S border. As the cells enter S phase the protection shrinks to 70 bp and remains unchanged throughout this phase. In mitosis the protection totally disappears, only to reappear in its extended form as the cells move into the next G1. These variations are reminiscent of those corresponding to the formation of the pre‐ and post‐replicative complexes described in yeast and Xenopus cells.

Alternative splicing in the human gene for the core protein A1 generates another hnRNP protein

The human hnRNP core protein A1 (34 kd) is encoded by a 4.6 kb gene split into 10 exons. Here we show that the A1 gene can be differentially spliced by the addition of an extra exon. The new transcript encodes a minor protein of the hnRNP complex, here defined A1B protein, with a calculated mol. wt of 38 kd, that coincides with a protein previously designated as B2 by some authors. In vitro translation of the mRNAs selected by hybridization with A1 cDNA produced two proteins of 34 and 38 kd; Northern blot analysis of poly(A)+ RNA from HeLa cells revealed that the abundance of the A1B mRNA was approximately 5% that of A1. The A1B protein was detected by Western blotting with an anti‐A1 monoclonal antibody both in enriched preparations of basic hnRNP proteins and in 40S hnRNP particles. The A1B protein exhibits a significantly higher affinity than A1 for ssDNA. The recombinant A1B protein, expressed in Escherichia coli, shows the same electrophoretic mobility and charge as the cellular one.