Homeotic proteins participate in the function of human-DNA replication origins.

Recent evidence points to homeotic proteins as actors in the crosstalk between development and DNA replication. The present work demonstrates that HOXC13, previously identified as a new member of human DNA replicative complexes, is a stable component of early replicating chromatin in living cells: it displays a slow nuclear dynamics due to its anchoring to the DNA minor groove via the arginine-5 residue of the homeodomain. HOXC13 binds in vivo to the lamin B2 origin in a cell-cycle-dependent manner consistent with origin function; the interaction maps with nucleotide precision within the replicative complex.

DNA replication, development and cancer: a homeotic connection?

The homeotic proteins are transcription factors, highly conserved in metazoan organisms, exerting a pivotal role in development and differentiation. They individually display a loose specificity for the DNA sequence they can bind, but operate mainly in multi-molecular associations that assure their target and function specificity. Homeotic proteins are known to play a role in the positive or negative regulation of cell proliferation.

The homeotic protein HOXC13 is a member of human DNA replication complexes.

The homeotic (and oncogenic) HOXC13 protein was shown to have an affinity for a DNA fragment corresponding to the sequence covered by the pre-replicative complex of the human lamin B2 replication origin. We show here that HOXC13 is a member of human replicative complexes. Our fluorescent fusion-protein data demonstrate that it co-localizes with replication foci of early-S cells and that this peculiar behaviour is driven by the homeodomain.

Molecular mechanics and DNA replication regulation.

Magnetic and optical tweezers are providing novel insights on the structure, energetics, and functional dynamics of biological macromolecules. The modulation of DNA topology has provided very appropriate opportunities to study with these technologies the energetic and mechanistic features of the action of DNA topoisomerases, the enzymes that maintain the physiological level of negative superhelicity in the genome. Modulation of the superhelical state of the DNA replication origins is essential for the initiation of DNA synthesis in prokaryotes and eukaryotes.

Molecular and structural transactions at human DNA replication origins.

The DNA replication origins of metazoan genomes are the sites of complex sequence-specific protein-DNA interactions determining their precise cycle of activation and deactivation, once only along each cell cycle. Some of the involved proteins have been identified (and particularly the essential six-protein Origin Recognition Complex, ORC) thanks to their homology with the proteins identified in yeast. Whereas in the latter organism ORC has a specific affinity for an origin consensus, metazoan (and human) ORC shows no sequence specificity and no origin consensus is identifiable in their genomes.

Functional interactions of DNA topoisomerases with a human replication origin.

The human DNA replication origin, located in the lamin B2 gene, interacts with the DNA topoisomerases I and II in a cell cycle-modulated manner. The topoisomerases interact in vivo and in vitro with precise bonds ahead of the start sites of bidirectional replication, within the pre-replicative complex region; topoisomerase I is bound in M, early G1 and G1/S border and topoisomerase II in M and the middle of G1. The Orc2 protein competes for the same sites of the origin bound by either topoisomerase in different moments of the cell cycle; furthermore, it interacts on the DNA with topoisomerase II during the assembly of the pre-replicative complex and with DNA-bound topoisomerase I at the G1/S border.

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 G(1), 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.

Start sites of bidirectional DNA synthesis at the human lamin B2 origin.

The initiation sites of bidirectional synthesis at the DNA replication origin located at the 3' end of the human lamin B2 gene were investigated. RNA-primed nascent DNA molecules were subjected to second-strand synthesis with appropriate primers, amplified by ligation-mediated polymerase chain reaction, and size fractionated. Evidence for precise start sites was obtained.

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.

Direct tRNA-protein interactions in ribosomal complexes.

Nucleotide residues in E. coli tRNA(Phe) interacting directly with proteins in pre- and posttranslocated ribosomal complexes have been identified by UV-induced cross-linking. In the tRNA(Phe) molecule located in the Ab-site (pretranslocated complex) residues A9, G18, A26 and U59 are cross-linked with proteins S10, L27, S7 and L2, respectively.

Determination of tRNA nucleotide residues directly interacting with proteins in the post- and pretranslocated ribosomal complexes.

Nucleotide residues of E. coli tRNA interacting directly with proteins in pre- and posttranslocated ribosomal complexes have been identified by analysis of photo-induced tRNA-protein cross-links. A9, G18, A26 and U59 residues of NAcPhePhe-tRNA, located in the Ab-site (pretranslocated complex) have been cross-linked with proteins S10, L27, S7 and L2 respectively.

Nucleotide residues of tRNA, directly interacting with proteins within the complex of the 30 S subunit of E. coli ribosome with poly(U) and NAcPhe-tRNA(Phe).

With the aid of photoinduced tRNA-protein cross-linking, nucleotide residues A21, U45 and U60 were shown to interact directly with proteins S5, S7 and S9 respectively, in the complex of the 30 S subunit of E. coli ribosome with poly(U) and NAcPhe-tRNA(Phe). These nucleotide residues are located in the central part of the L-form in the tertiary structure of RNA.

Induction of polynucleotide-protein cross-linkages by ultraviolet irradiation. Peculiarities of the high-intensity laser pulse irradiation.

The efficiency and specificity of RNA-protein cross-linking in the 30S subunit of Escherichia coli ribosomes, induced by low-intensity (10(15) photons cm-2 s-1, 254 nm) and high-intensity [(1.6-6.8) X 10(24) photons cm-2 s-1, 266 nm, pulse duration 10(-8) s] ultraviolet radiation, are studied.

Structural characteristics and classification of some tRNA-binding sites of elongating Escherichia coli ribosome.

Ultraviolet(254 nm)-irradiation-induced cross-linkages in ribosomal complexes allowed identification of proteins in contact with tRNA at different elongation steps. Both the set and the ratio of cross-linked proteins, i.e.

[General method of isolation and analysis of polynucleotide fragments cross-linked with proteins].

A fragment of 16S RNA, cross-linked to S7 protein by UV irradiation of the 30S subunit of E. coli ribosome, was obtained by the action of T1 ribonuclease on the irradiated nucleoprotein. The digest was treated with polynucleotide kinase in the presence of [gamma-32P]ATP and the S7-cross-linked oligonucleotides were isolated.

[Proteins contacting with peptidyl-tRNA at the A-site of the Escherichia coli ribosome after enzymatic and non-enzymatic binding of aminoacyl-tRNA].

Proteins contacting (directly interacting) with peptidyl-tRNA in the A-site of E. coli ribosome were determined by means of ultraviolet-induced RNA-protein cross-linking. It has been shown that upon enzymatic binding of Phe-tRNAPhe with the posttranslocated ribosome and following transpeptidation, the peptidyl-tRNAPhe directly interacts with proteins S5, S10, L6, L16 and S13/S14/L27, while upon non-enzymatic binding--with S5, S10, L2, L6 and L16.

Intersubunit RNA-protein contacts in pre- and post-translocated E. coli ribosome.

Ribosomal proteins participating in intersubunit RNA-protein contacts (directly interacting with RNA of the opposite subunit) were determined by means of ultraviolet-induced cross-links in pre- and post-translocated ribosomal complexes, as well as in the free 70 S ribosome (tight couple) of E. coli. In these 3 complexes at least L1 and L9 proteins interact with 16 S RNA, while S6, S9/11 and S15 react with 23 S RNA.

[Ribosomal proteins interacting with Phe-tRNAPhe during enzymatic binding with translating ribosome before and after the release of the elongation factor EF-Tu].

Proteins, directly interacting with tRNA in R- and A-sites of E. coli ribosome were determined by means of ultraviolet-induced RNA-protein cross-links. It is shown, that tRNAPhe in the R-site (upon enzymatic binding of the ternary complex Phe-tRNAPhe.

[Contacts of ribosomal proteins with tRNAPhe and 16S RNA in analogs of the 30S initiation complex].

Direct RNA-protein contacts have been studied by means of ultraviolet-induced (254 nm) cross-links inside complexes of NAcPhe-tRNAPhe, Phe-tRNAPhe and deacylated tRNAPhe with poly(U)-charged 30S subunit of Escherichia coli ribosome. In the first two complexes tRNA directly contacts with the similar sets of proteins (S4, S5, S7, S9/S11; S6 and S8 are found only in the second complex). These sets are similar to that in the fMet-tRNAfMet X 30S X mRNA complex, evidencing similar disposition of tRNAs in these three complexes.

[Changes in subunit conformation and their reciprocal configuration in the transition from the pretranslocated to the posttranslocated state].

RNA-protein contacts in pretranslocated and posttranslocated states of E. coli ribosomes have been determined by means of UV-induced cross-linking. In the two functional states as well as in free 70C ribosome, the same proteins are involved in RNA-protein intersubunit contacts, located in the region of L1 protuberance (left side of 70S ribosome).

Preparation and properties of monomercurated tRNA.

Monomercurated tRNA has been prepared by exhaustive treatment of mercaptoethanol on polymercurated tRNA under non-denaturing conditions. The remained mercury atom is stable toward ultraviolet (254 nm) irradiation up to absorption of 100 quanta/nucleotide, but could be easily removed by mercaptoethanol under denaturing conditions. Monomercurated tRNA quantitatively binds to thiopropyl-Sepharose and can be completely desorbed by mercaptoethanol-containing solutions.