The Arabidopsis homeobox gene, ATHB16, regulates leaf development and the sensitivity to photoperiod in Arabidopsis

This report describes the characterisation of ATHB16, a novel Arabidopsis thaliana homeobox gene, which encodes a homeodomain-leucine zipper class I (HDZip I) protein. We demonstrate that ATHB16 functions as a growth regulator, potentially as a component in the light-sensing mechanism of the plant. Endogenous ATHB16 mRNA was detected in all organs of Arabidopsis, at highest abundance in rosette leaves. Reduced levels of ATHB16 expression in transgenic Arabidopsis plants caused an increase in leaf cell expansion and consequently an increased size of the leaves, whereas leaf shape was unaffected. Transgenic plants with increased ATHB16 mRNA levels developed leaves that were smaller than wild-type leaves. Therefore, we suggest ATHB16 to act as a negative regulator of leaf cell expansion. Furthermore, the flowering time response to photoperiod was increased in plants with reduced ATHB16 levels but reduced in plants with elevated ATHB16 levels, indicating that ATHB16 has an additional role as a suppressor of the flowering time sensitivity to photoperiod in wild-type Arabidopsis. As deduced from the response of transgenic plants with altered levels of ATHB16 expression in hypocotyl elongation assays, the gene may act to regulate plant development as a mediator of a blue light response.     

Phosphorylation by cdc2 kinase modulates DNA binding activity of high mobility group I nonhistone chromatin protein

Chromatin high mobility group protein I (HMG-I) is a mammalian nonhistone protein that has been demonstrated both in vitro and in vivo to preferentially bind to A.T-rich sequences of DNA. Recently the DNA-binding domain peptide that specifically mediates the in vitro interaction of high mobility group protein (HMG)-I with the narrow minor groove of A.T-DNA has been experimentally determined. Because of its predicted secondary structure, the binding domain peptide has been called "the A.T hook" motif. Previously we demonstrated that the A.T hook of murine HMG-I protein is specifically phosphorylated by purified mammalian cdc2 kinase in vitro and that the same site(s) are also phosphorylated in vivo in metaphase-arrested cells. We also found that the DNA binding affinity of short synthetic binding domain peptides phosphorylated in vitro by cdc2 kinase was significantly reduced compared with unphosphorylated peptides. Here we extend these findings to intact natural and recombinant HMG-I proteins. We report that the affinity of binding of full-length HMG-I proteins to A.T-rich sequences is highly dependent on ionic conditions and that phosphorylation of intact proteins by cdc2 kinase reduces their affinity of in vitro binding to A.T-DNA by about 20-fold when assayed near normal mammalian physiological salt concentrations. Furthermore, in cell synchronization studies, we demonstrated that murine HMG-I proteins are phosphorylated in vivo in a cell cycle-dependent manner on the same amino acid residues modified by purified cdc2 kinase in vitro. Together these results strongly support the assertion that HMG-I proteins are natural substrates for mammalian cdc2 kinase in vivo and that their cell cycle-dependent phosphorylation by this enzyme(s) significantly modulates their DNA binding affinity, thereby possibly altering their biological function(s).     

Pax-3-DNA interaction: flexibility in the DNA binding and induction of DNA conformational changes by paired domains.

The mouse Pax-3 gene encodes a protein that is a member of the Pax family of DNA binding proteins. Pax-3 contains two DNA binding domains: a paired domain (PD) and a paired type homeodomain (HD). Both domains are separated by 53 amino acids and interact synergistically with a sequence harboring an ATTA motif (binding to the HD) and a GTTCC site (binding to the PD) separated by 5 base pairs. Here we show that the interaction of Pax-3 with these two binding sites is independent of their angular orientation. In addition, the protein spacer region between the HD and the PD can be shortened without changing the spatial flexibility of the two DNA binding domains which interact with DNA. Furthermore, by using circular permutation analysis we determined that binding of Pax-3 to a DNA fragment containing a specific binding site causes conformational changes in the DNA, as indicated by the different mobilities of the Pax-3-DNA complexes. The ability to change the conformation of the DNA was found to be an intrinsic property of the Pax-3 PD and of all Pax proteins that we tested so far. These in vitro studies suggest that interaction of Pax proteins with their specific sequences in vivo may result in an altered DNA conformation.     

Functional analysis at the Cys706 residue of the retinoblastoma protein.

A missense mutation at cysteine 706, resulting in a retinoblastoma (RB) protein defective in phosphorylation and oncoprotein binding, has been isolated from a human tumor cell line. Since this residue is conserved in murine RB and in the related p107 protein, we studied the activity of in vitro mutants flanking this position. These experiments demonstrated that the thiol atom at codon 706 does not possess intrinsic functional activity as small polar or nonpolar residues could substitute at either codons 706 or 707, while bulkier R-group changes in these positions interfered with in vitro oncoprotein binding or in vivo protein phosphorylation. A series of missense mutants in an adjacent leucine repeat domain also demonstrated a loss of oncoprotein binding that was proportional to the magnitude of amino acid substitutions. To determine whether the cysteine 706 --> phenylalanine RB mutant retained any protein binding activity, we examined its ability to precipitate MYC, which was recently identified as a potential RB-associated protein. These experiments demonstrated that the mutant RB product is capable of binding in vitro to c-myc and L-myc proteins with comparable affinity as wild-type RB. These findings raise questions about the functional role of the RB:MYC interactions and emphasize important differences in the binding patterns between MYC and the other RB-associated proteins.     

Functional homology between the sequence-specific DNA-binding proteins nuclear factor I from HeLa cells and the TGGCA protein from chicken liver.

Nuclear factor I from HeLa cells, a protein with enhancing function in adenovirus DNA replication, and the chicken TGGCA protein are specific DNA-binding proteins that were first detected by independent methods and that appeared to have similar DNA sequence specificity. To test whether they are homologous proteins from different species we have compared (i) their DNA binding properties and (ii) their function in reconstituted adenovirus DNA replication systems. Using deletion and substitution mutants derived from the DNA binding site on the adenovirus 2 inverted terminal repeat, it was found that the two proteins protect the same 24-nucleotide region of both strands against DNase I digestion and that they have identical minimal recognition sequences of 15 bp containing dyad symmetry. Like nuclear factor I, the TGGCA protein enhances the initiation reaction of adenovirus 2 DNA replication in vitro in a DNA recognition site-dependent manner.