Photocross-linking of an oriented DNA repair complex. Ku bound at a single DNA end.

Ku protein binds broken DNA ends, triggering a double-strand DNA break repair pathway. The spatial arrangement of the two Ku subunits in the initial Ku-DNA complex, when the Ku protein first approaches the broken DNA end, is not well defined. We have investigated the geometry of the complex using a novel set of photocross-linking probes that force Ku protein to be constrained in position and orientation, relative to a single free DNA end. Results suggest that this complex is roughly symmetric and that both Ku subunits make contact with an approximately equal area of the DNA. The complex has a strongly preferred orientation, with Ku70-DNA backbone contacts located proximal and Ku80-DNA backbone contacts located distal to the free end. Ku70 also contacts functional groups in the major groove proximal to the free end. Ku80 apparently does not make major groove contacts. Results are consistent with a model where the Ku70 and Ku80 subunits contact the major and minor grooves of DNA, respectively.     

Conservation of Hox/ParaHox-related genes in the early development of a cnidarian.

To clarify the relationship between axial patterning in cnidarians and bilaterians, we have investigated the embryonic development of the hydrozoan Podocoryne carnea. The expression of Hox-like homeobox genes was analyzed by RT-PCR and in situ hybridization. Cnox1-Pc, an anterior Hox gene, is a maternal message. It is present throughout larval development, first weakly in all blastomeres and later restricted mostly to the anterior pole of the planula. Gsx, an anterior ParaHox gene, is first seen in the anterior endoderm but also extends into posterior regions. Cnox4-Pc, an orphan Hox-like gene, is expressed in the egg as a ring-shaped cloud around the germinal vesicle. After fertilization, the message remains in most animal blastomeres. When the embryo elongates in late blastula, staining is restricted to a few cells at the posterior pole where gastrulation will start. However, once gastrulation starts, the Cnox4-Pc signal disappears and is absent in later stages of larval development. Phylogenetic analysis shows that not all cnidarian Hox-like genes have recognizable orthologues in bilaterian groups. However, the expression analysis of Cnox1-Pc and Gsx correlates to some extent with the expression pattern of cognate genes of bilaterians, confirming the conservation of genes involved in organizing animal body plans and their putative common ancestral origin.     

Hox homeodomain proteins exhibit selective complex stabilities with Pbx and DNA.

Eight of the nine homeobox genes of the Hoxb locus encode proteins which contain a conserved hexapeptide motif upstream from the homeodomain. All eight proteins (Hoxb-1-Hoxb-8) bind to a target oligonucleotide in the presence of Pbx1a under conditions where minimal or no binding is detected for the Hox or Pbx1a proteins alone. The stabilities of the Hox-Pbx1a-DNA complexes vary >100-fold, with the proteins from the middle of the locus (Hoxb-5 and Hoxb-6) forming very stable complexes, while Hoxb-4, Hoxb-7 and Hoxb-8 form complexes of intermediate stability and proteins at the 3'-side of the locus (Hoxb-1-Hoxb-3) form complexes which are very unstable. Although Hox-b proteins containing longer linker sequences between the hexapeptide and homeodomains formed unstable complexes, shortening the linker did not confer complex stability. Homeodomain swapping experiments revealed that this motif does not independently determine complex stability. Naturally occurring variations within the hexapeptides of specific Hox proteins also do not explain complex stability differences. However, two core amino acids (tryptophan and methionine) which are absolutely conserved within the hexapeptide domains appear to be required for complex formation. Removal of N- and C-terminal flanking regions did not influence complex stability and the members of paralog group 4 (Hoxa-4, b-4, c-4 and d-4), which share highly conserved hexapeptides, linkers and homeodomains but different flanking regions, form complexes of similar stability. These data suggest that the structural features of Hox proteins which determine Hox-Pbx1a-DNA complex stability reside within the precise structural relationships between the homeodomain, hexapeptide and linker regions.     

Conservation of a functional hierarchy between mammalian and insect Hox/HOM genes.

We have generated several transgenic Drosophila strains containing different mouse Hox genes under heat shock control and studied how their generalized expression affects Drosophila larval patterns. We find that they have spatially restricted effects which correlate with their genetic order and expression pattern in the mouse; as they are expressed more posteriorly in the mouse, they have more extensive effects in Drosophila. The generalized expressions of Hoxd-8 and d-9 modify Drosophila anterior head segment(s), but have no effect in the rest of the body. Hoxd-10 expression affects head and thorax, but not the abdomen. Finally, Hoxd-11 alters head, thorax not the abdomen. Finally, Hoxd-11 alters head, thorax and abdomen. The developmental effect of the Hox genes consists of a homeotic transformation of the affected segment(s), which exhibit a 'ground' pattern similar to that obtained in the absence of homeotic information, suggesting that Hox genes are able to inactivate Drosophila homeotic genes, but do not specify a pattern of their own. A partial exception is Hoxd-11 which, even though it has a general suppressing effect, can also activate the resident Abdominal-B and empty spiracles genes in ectopic positions. Our results strongly suggest a general conservation of the functional hierarchy of homeotic genes that correlates with genetic order and expression patterns.     

Deconvolution of a complex target using DNA aptamers

In vitro selection of single-stranded nucleic acid aptamers from large random sequence libraries is now a straightforward process particularly when screening with a single target molecule. These libraries contain considerable shape diversity as evident by the successful isolation of aptamers that bind with high affinity and specificity to chemically diverse targets. We propose that aptamer libraries contain sufficient shape diversity to allow deconvolution of a complex mixture of targets. Using unfractionated human plasma as our experimental model, we aim to develop methods to obtain aptamers against as many proteins as possible. To begin, it is critical that we understand how aptamer populations change with increasing rounds of in vitro selection when using complex mixtures. Our results show that sequence representation in the selected population changes dramatically with increasing rounds of selection. Certain aptamer families were apparent after only three selection rounds. Two additional cycles saw a decline in the relative abundance of these families and the emergence of yet another family that accounted for more than 60% of sequences in the pool. To overcome this population convergence, an aptamer-based target depletion method was developed, and the library screen was repeated. The previous dominant family effectively disappeared from the selected populations but was replaced by other aptamer families. Insights gained from these initial experiments are now being applied in the creation of second generation plasma protein screens and also to the analysis of other complex biological targets.     

Structural isomers of bis-PNA bound to a target in duplex DNA

Upon binding of a decamer bis-PNA (H-Lys-TTCCTCTCTT-(eg1)(3)-TTCTCTCCTT-LysNH(2)) to a complementary target in a double-stranded DNA fragment, three distinct complexes were detected by gel mobility shift analysis. Using in situ chemical probing techniques (KMnO(4) and DMS) it was found that all three complexes represent bona fide sequence-specific PNA binding to the designated target, but the complexes were structurally different. One complex that preferentially formed at higher PNA concentrations contains two bis-PNA molecules per DNA target, whereas the other two complexes are genuine triplex invasion clamped structures. However, these two latter complexes differ by the path relative to the DNA target of the flexible ethylene-glycol linker connecting the two PNA oligomers that comprise a bis-PNA. We distinguish between one in which the linker wraps around the non-target DNA strand, thus making this strand part of the triplex invasion complex and another complex that encompass the target strand only. The implications of these results are discussed in terms of DNA targeting by synthetic ligands.     

Regulation of adeno-associated virus DNA replication by the cellular TAF-I/set complex

The Rep proteins of the adeno-associated virus (AAV) are required for viral replication in the presence of adenovirus helper functions and as yet poorly characterized cellular factors. In an attempt to identify such factors, we purified Flag-Rep68-interacting proteins from human cell lysates. Several polypeptides were identified by mass spectrometry, among which was ANP32B, a member of the acidic nuclear protein 32 family which takes part in the formation of the template-activating factor I/Set oncoprotein (TAF-I/Set) complex. The N terminus of Rep was found to specifically bind the acidic domain of ANP32B; through this interaction, Rep was also able to recruit other members of the TAF-I/Set complex, including the ANP32A protein and the histone chaperone TAF-I/Set. Further experiments revealed that silencing of ANP32A and ANP32B inhibited AAV replication, while overexpression of all of the components of the TAF-I/Set complex increased de novo AAV DNA synthesis in permissive cells. Besides being the first indication that the TAF-I/Set complex participates in wild-type AAV replication, these findings have important implications for the generation of recombinant AAV vectors since overexpression of the TAF-I/Set components was found to markedly increase viral vector production.     

Isolation of Hox genes from the scyphozoan Cassiopeia xamachana: implications for the early evolution of Hox genes.

The isolation of Hox genes from two cnidarian groups, the Hydrozoa and Anthozoa, has sparked hypotheses on the early evolution of Hox genes and a conserved role for these genes for defining a main body axis in all metazoan animals. We have isolated the first five Hox genes, Scox-1 to Scox-5, from the third cnidarian class, the Scyphozoa. For all but one gene, we report full-length homeobox plus flanking sequences. Four of the five genes show close relationship to previously reported Cnox-1 genes from Hydrozoa and Anthozoa. One gene, Scox-2, is an unambiguous homologue of Cnox-2 genes known from Hydrozoa, Anthozoa, and also Placozoa. Based on sequence similarity and phylogenetic analyses of the homeobox and homeodomain sequences of known Hox genes from cnidarians, we suggest the presence of at least five distinct Hox gene families in this phylum, and conclude that the last common ancestor of the Recent cnidarian classes likely possessed a set of Hox genes representing three different families, the Cnox-1, Cnox-2, and Cnox-5 families. The data presented are consistent with the idea that multiple duplication events of genes have occurred within one family at the expense of conservation of the original set of genes, which represent the three ancestral Hox gene families.     

MicroRNA mediates DNA methylation of target genes

Small RNAs represented by microRNA (miRNA) plays important roles in plant development and responds to biotic and abiotic stresses. Previous studies have placed special emphasis on gene-repression mediated by miRNA. In this work, the DNA methylation pattern of microRNA genes (MIRs) was interrogated. Full-length cDNA and EST were used to confirm the entity of pri-miRNA. In parallel, miRNA in 24 nucleotides (nt) was pooled to detect chromatin modification effect by using bisulfite sequencing data. 97 MIRs were supported by full-length cDNA and 30 more were hit by EST. Notably, methylation levels of conserved MIRs were significantly lower than the non-conserved at all contexts (CG, CHG, and CHH). Additionally, a substantial part of 24-nt miRNA was able to induce target site methylation, providing a broader perspective for researchers.     

Colinear and segmental expression of amphioxus Hox genes.

The cephalochordate amphioxus has a single Hox gene cluster. Here we describe the genomic organization of four adjacent amphioxus genes, AmphiHox-1 to AmphiHox-4, together with analysis of their spatiotemporal expression patterns. We demonstrate that these genes obey temporal colinearity and that three of the genes also obey spatial colinearity in the developing neural tube. AmphiHox-1, AmphiHox-3, and AmphiHox-4 show segmental modulation of their expression levels, a two-segment phasing of spatial colinearity, and, at least for AmphiHox-4, asymmetrical expression. AmphiHox-2 is unlike other amphioxus Hox genes: it does not obey spatial colinearity and it has no positional expression in the neural tube. AmphiHox-2 is expressed in the preoral pit of larvae, from which the homologue of the anterior pituitary develops. We suggest that the ancestral role of chordate Hox genes was primarily in the neural tube and that chordate Hox genes can functionally diverge in a manner analogous to that of Drosophila ftz or zen.