Fabio Cobianchi

DNA-binding proteins and DNA-unwinding enzymes in eukaryotes

Abstract Two classes of proteins in eukaryotic cells are involved in the active unwinding of double-stranded DNA and in the stabilization of the single-strands: DNA-dependent ATPases and DNA-binding proteins. The activity of both types of molecules appears to be coordinated and simultaneous during recombination and/or the advancement of the growing fork during DNA replication.

Presence of transcription signals in two putative DNA replication origins of human cells.

We describe the purification and cloning of human DNA replicated at the onset of S phase in HL60 cells synchronized with aphidicolin. A survey of the overall structural properties of these sequences did not show any distinctive features except for an enrichment in Cot0 DNA. The two longer fragments were completely sequenced and studied in more detail. Both were shown to contain transcriptional signals associated with promoters and/or enhancers, such as the binding sites of Sp1, T antigen and nuclear factor III. In one instance, a binding site for a known cellular transcription factor (USF/MLTF) was located inside the sequence by footprinting. Accordingly, by CAT assay and Northern blot, the same sequence was shown to contain an active promoter. The significance of these findings with respect to the role of transcription in initiation of DNA replication at the origin is discussed. None of the tested fragments exhibited autonomously replicating sequence (ARS) activity in transfected cells. The problems connected with the detection of ARS activity in human cells are critically examined.

Human hnRNP protein A1: a model polypeptide for a structural and genetic investigation of a broad family of RNA binding proteins.

The hnRNP fiber is the substrate on which pre-mRNA processing occurs. The protein moiety of the fiber (hnRNP proteins) constitutes a broad family of RNA binding proteins that revealed, upon molecular analysis, a number of interesting features.Heterogeneous nuclear ribonucleoprotein A1 is a major component of the human hnRNP complex. In recent years this protein has attracted great attention because of several emerging evidences of its direct involvement in pre-mRNA processing and it has become one of the best characterized RNA binding proteins. Detailed knowledge of the structure of protein A1 has laid the basis for the understanding of its function, and for this reason A1 can be considered as a model polypeptide for the investigation of a large number of RNA binding proteins.In this work we report recent findings regarding the binding properties of protein A1 as well as new data on the gene structure of A1 and of its closely related hnRNP protein A2. Our results show that a single A1 molecule contains the determinants for simultaneous binding of two single-stranded nucleic acid molecules and we demonstrate that the glycine-rich domain of A1, isolated from the rest of the molecule, is capable of sustaining protein-protein interactions. These features probably account for the reannealing activity of the protein and for its capacity to modulate the binding of snRNPs to intron sequencesin vitro. Comparison of A1 and A2 gene sequences revealed a remarkable conservation of the overall structural organization, suggesting important functions for the different structural elements.

A DNA dependent ATPase from HeLa cells

Abstract The purification and the properties of the major DNA dependent ATPase from HeLa cells are described. This enzyme is present in the nucleus and in the cytoplasm in approximately equal amounts. It has a Mr of about 110000 dalton and it hydrolyzes ATP (and dATP) to ADP+Pi only in the presence of single-stranded DNA. The enzyme shows an ATP dependent unwinding activity on DNA duplex, with a 3′ to 5′ polarity of the unwound strand. Under certain conditions the enzyme is able to stimulate the activity of DNA polymeraseα on appropriate DNA templates. Such stimulation is synergistic with that exerted by a DNA binding protein from calf thymus.

Searching for Proteins and Sequences of DNA Replication in Mammalian Cells

We have approached the problem of describing the process of DNA replication of mammalian cells at the molecular level from two sides: 1) Purification and description of the properties of proteins (presumably) involved in the advancement of the growing fork. 2) Attempts at cloning sequences of human DNA allowing autonomous replication in mammalian cells of plasmids bearing them.