BAC manipulations for making BAC transgene arrays.

Chromosome tagging using lac or tet operator repeats for in vivo visualization of chromosome dynamics has now become a standard methodology used in a range of organisms. One variation of this approach has been to build transgene arrays creating artificial chromosome blocks to study various aspects of chromatin structure, transcription, replication, or DNA repair. Previously, plasmid transgenes with or without subsequent gene amplification have been used to build these arrays. However, plasmid arrays typically show heterochromatic properties, while gene amplification typically results in chromosome instability of the amplified regions. To avoid these problems, we are now building transgene arrays from large genomic DNA inserts cloned in bacterial artificial chromosomes (BAC). These BAC transgenes show transcriptional levels within several fold of endogenous genes while also exhibiting targeting to specific nuclear compartments similar to the targeting of the endogenous genes. Here we describe Tn5 transposition and BAC recombineering methods used to retrofit BACs for their use in building BAC transgene arrays. This includes insertion of operator repeats and selectable markers into these BACs as well as targeted insertion or deletion of BAC sequences.

Hsp70 gene association with nuclear speckles is Hsp70 promoter specific.

Many mammalian genes localize near nuclear speckles, nuclear bodies enriched in ribonucleic acid-processing factors. In this paper, we dissect cis-elements required for nuclear speckle association of the heat shock protein 70 (Hsp70) locus. We show that speckle association is a general property of Hsp70 bacterial artificial chromosome transgenes, independent of the chromosome integration site, and can be recapitulated using a 2.8-kilobase HSPA1A gene fragment. Association of Hsp70 transgenes and their transcripts with nuclear speckles is transcription dependent, independent of the transcribed sequence identity, but dependent on the Hsp70 promoter sequence. Transgene speckle association does not correlate with the amount of transcript accumulation, with large transgene arrays driven by different promoters showing no speckle association, but smaller Hsp70 transgene arrays with lower transcript accumulation showing high speckle association. Moreover, despite similar levels of transcript accumulation, Hsp70 transgene speckle association is observed after heat shock but not cadmium treatment. We suggest that certain promoters may direct specific chromatin and/or transcript ribonucleoprotein modifications, leading to nuclear speckle association.

Dynamic plasticity of large-scale chromatin structure revealed by self-assembly of engineered chromosome regions.

Interphase chromatin compaction well above the 30-nm fiber is well documented, but the structural motifs underlying this level of chromatin folding remain unknown. Taking a reductionist approach, we analyzed in mouse embryonic stem (ES) cells and ES-derived fibroblasts and erythroblasts the folding of 10-160-megabase pair engineered chromosome regions consisting of tandem repeats of bacterial artificial chromosomes (BACs) containing approximately 200 kilobases of mammalian genomic DNA tagged with lac operator (LacO) arrays. Unexpectedly, linear mitotic and interphase chromatid regions formed from noncontiguously folded DNA topologies. Particularly, in ES cells, these model chromosome regions self-organized with distant sequences segregating into functionally distinct, compact domains. Transcriptionally active and histone H3K27me3-modified regions positioned toward the engineered chromosome subterritory exterior, with LacO repeats and the BAC vector backbone localizing within an H3K9me3, HP1-enriched core. Differential compaction of Dhfr and alpha- and beta-globin transgenes was superimposed on dramatic, lineage-specific reorganization of large-scale chromatin folding, demonstrating a surprising plasticity of large-scale chromatin organization.

Large-scale chromatin structure of inducible genes: transcription on a condensed, linear template.

The structure of interphase chromosomes, and in particular the changes in large-scale chromatin structure accompanying transcriptional activation, remain poorly characterized. Here we use light microscopy and in vivo immunogold labeling to directly visualize the interphase chromosome conformation of 1-2 Mbp chromatin domains formed by multi-copy BAC transgenes containing 130-220 kb of genomic DNA surrounding the DHFR, Hsp70, or MT gene loci. We demonstrate near-endogenous transcription levels in the context of large-scale chromatin fibers compacted nonuniformly well above the 30-nm chromatin fiber. An approximately 1.5-3-fold extension of these large-scale chromatin fibers accompanies transcriptional induction and active genes remain mobile. Heat shock-induced Hsp70 transgenes associate with the exterior of nuclear speckles, with Hsp70 transcripts accumulating within the speckle. Live-cell imaging reveals distinct dynamic events, with Hsp70 transgenes associating with adjacent speckles, nucleating new speckles, or moving to preexisting speckles. Our results call for reexamination of classical models of interphase chromosome organization.