Adapter annealing to engineer restriction enzyme sites at cloning junctions

Heterobifunctional modification of DNA for conjugation to solid surfaces

Many biosensors, DNA arrays, and next-generation DNA sequencing technologies need common methods for end modification of random DNA sequences generated from a sample of DNA. Surface immobilization of chemically modified DNA is often the first step in creating appropriate sensing platforms. We describe a simple technique for efficient heterobifunctional modification of arbitrary double-stranded DNA fragments with chosen chemical groups. The modification requires the use of short (10-20 base pairs) synthetic adaptors having desired terminal functional groups and installs known sequences, which can be used for hybridization of primers in the sequencing-by-synthesis approaches. The method, based on ligation under optimized conditions, is selective and provides high yields of the target heterobifunctional DNA product. An additional two-step procedure can be applied to select further for the desired bifunctionalized product using PCR amplification with a chemically modified primer. Both functional groups in the modified DNA are chemically active and can be used in surface immobilization of the DNA strands to create the surface of a biosensor or sequencing chip.

A pair of mouse KRAB zinc finger proteins modulates multiple indicators of female reproduction

Krüppel-associated box-zinc finger proteins (KRAB-ZFPs) are the largest class of transcriptional regulators in mammals, yet few have been assigned biological roles. Cloning the genes underlying the regulator of sex-limitation (rsl) phenotype, in which the normally male-specific sex-limited protein (SLP) is expressed in female mice, identified two KRAB-ZFPs, Rsl1 and Rsl2, as influencing sexually dimorphic liver gene expression. Combined absence of both repressors in rsl mice leads to increased expression in female liver of major urinary proteins (MUPs) and certain enzymes of steroid metabolism, as well as SLP. We hypothesized that this altered gene expression might affect reproductive physiology in rsl females. Urinary MUP (uMUP) concentration varied with the estrous cycle in both wt and rsl females but was consistently higher in rsl urine. A behavioral odor test revealed that wild-type (wt) males preferred rsl to wt females, possibly due to elevated uMUPs providing greater pheromone presentation. To ascribe activity to Rsl1, Rsl2, or both, the genes were individually expressed as liver-specific transgenes. RSL2 overexpression accentuated uMUP fluctuations across the estrous cycle, whereas RSL1 overexpression did not. In addition, puberty onset, as indicated by vaginal opening (VO), occurred 2 days earlier in rsl females, and excess RSL2, but not RSL1, restored VO timing to wt. Hence, transcriptional repression by RSL in liver modifies female mouse reproduction via targets that likely impact both hormonal and pheromonal cues. The large and rapidly diversifying KRAB-ZFP family may modulate biological processes, including reproduction, to confer individual differences that may isolate populations and ultimately lead to speciation.

Regulator of sex-limitation KRAB zinc finger proteins modulate sex-dependent and -independent liver metabolism

Krüppel-related zinc finger proteins (KRAB-zfps) comprise the largest mammalian transcription factor family, but their specific functions are largely unknown. Two KRAB-zfps, regulator of sex-limitation (Rsl) 1 and Rsl2, repress expression of the mouse sex-limited protein (Slp) gene, the hallmark of Rsl activity, as well as some other male-predominant liver genes. This phenotype suggests Rsl modifies sex-specific transcription. The scope of Rsl control was determined by expression profiling of liver RNA from wild-type (wt), rsl, and transgenic mice with hepatic overexpression of Rsl1 or Rsl2. About 7.5% of the liver transcriptome was Rsl-responsive. More genes in males than females were affected by the loss of Rsl (e.g., in rsl mice), whereas Rsl overexpression altered more transcripts in females than males. Rsl dramatically repressed some female-predominant genes, but most were modestly (1.25- to 2-fold) influenced. In males, most Rsl-responsive genes unexpectedly expressed at lower levels in rsl than wt, suggesting not all are direct targets of Rsl repression. Gene Ontology analysis showed Rsl targets enriched in pathways of cholesterol, steroid, and lipid metabolism, linking Rsl to energy balance. In accord with this, blood glucose levels were less in male rsl than wt mice, and less responsive to fasting and refeeding. rsl mice were also leaner than wt, consistent with their hepatic regulation of phosphoenolpyruvate carboxykinase 1 and stearoyl-Coenzyme A desaturase 1. Altogether, Rsl's effect on sexually dimorphic and metabolically sensitive liver gene expression suggests a role for KRAB-zfps as broad genetic modulators of individual adaptation.