Prophage λ induction test (inductest) of anti-tumor antibiotics

A total of 20 compounds, consisting of anti-tumor antibiotics and their derivatives, were examined for their ability to induce prophage λ in Escherichia coli GY5027. Mitomycin C, daunomycin, adriamycin, bleomycin and bleomycin analogs, induced prophage λ without S9 mix. Aclacinomycin A and its monodemethyl derivative did not induce prophage λ, but N-didemethylaclacinomycin A did. Actinomycin D, neothramycin, 1-deoxy-pyrromycin, adriamycinone, aklavinone and daunomycinone did not induce prophage λ either in the presence or absence of S9 mix.     

Regulation of replication of λ phage and λ plasmid DNAs at low temperature

It was previously demonstrated that while lysogenic development of bacteriophage λ in Escherichia coli proceeds normally at low temperature (20–25° C), lytic development is blocked under these conditions owing to the increased stability of the phage CII protein. This effect was proposed to be responsible for the increased stimulation of the p _E promoter, which interferes with expression of the replication genes, leading to inhibition of phage DNA synthesis. Here we demonstrate that the burst size of phage λcIb2, which is incapable of lysogenic development, increases gradually over the temperature range from 20 to 37° C, while no phage progeny are observed at 20° C. Contrary to previous reports, it is possible to demonstrate that p _E promoter activation by CII may be more efficient at lower temperature. Using density-shift experiments, we found that phage DNA replication is completely blocked at 20° C. Phage growth was also inhibited in cells overexpressing cII, which confirms that CII is responsible for inhibition of phage DNA replication. Unexpectedly, we found that replication of plasmids derived from bacteriophage λ is neither inhibited at 20° C nor in cells overexpressing cII. We propose a model to explanation the differences in replication observed between λ phage and λ plasmid DNA at low temperature. Received: 30 December 1997 / Accepted: 25 February 1998     

Accelerated cyclization of λ DNA

In the presence of spermidine, the DNA molecule of the bacteriophage λ undergoes a coil-globule transition. We report here that the cyclization of this molecule in its globular state is greatly accelerated (by more than 10⁴ -fold) in comparison with the cyclization reaction taking place in the coil conformation.     

Regulation of DNA topoisomerase IIα stability by the ECV ubiquitin ligase complex

In this study, we attempted to elucidate the E3 ubiquitin ligase for topo IIα. When cullins and VHL were ectopically expressed in HT1080 and HEK293T cells, topo IIα was degraded most prominently in cullin 2- and VHL-expressing cells. Cullin 2 and the β domain (aa 114-123) of VHL, a subunit of the ECV (Elongin B/C-cullin 2-VHL protein) complex, specifically interact with the ATPase domain of topo IIα. We identified that topo IIα associated with endogenous Elongin C. In HT1080 cells co-transfected with deletion mutants of topo IIα GRDD (glucose-regulated destruction domain) and VHL, topo IIα was degraded by VHL expression. These results demonstrate that ECV acts as E3 ubiquitin ligase targeting GRDD-independent topo IIα to the ubiquitin-proteasome pathway.     

Transduction of Gal+ by Coliphage T1 I. Role of Hybrids of Bacterial and Prophage λ Deoxyribonucleic Acid

Hybrids of lambda and adjacent bacterial deoxyribonucleic acid carried in T1 particles were able to transduce Gal(+) with a greatly increased efficiency to strains which were not immune to lambda compared to immune strains. The enhanced transduction was dependent on a functional recA(+) gene in the recipient. Mutations of the donor's lambda prophage which abolished the function of either the cI, O, or P genes in the recipients led to a further enhancement of transduction. The rate of transduction of a nonlysogenic recipient such as W3350 by the hybrid particles may be as much as 140 times greater than transduction of the lysogenic recipient W3350(lambda). In addition to the effect of lambda immunity in blocking enhanced transduction, mutations of the N gene of the donor's lambda prophage abolished enhanced transduction. Mutations in the red, int, xis, and Q genes of the donor's prophage had no significant effect on transduction. The hybrids which mediated the enhanced transduction are called (lambda-gal)T1.     

High-Resolution Physical Map of the Immunoglobulin λ Variant Gene Cluster Assembled by Quantitative DNA Fiber Mapping

Quantitative DNA fiber mapping (QDFM) allows rapid construction of near-kilobase-resolution physical maps by hybridizing specific probes to individual stretched DNA molecules. We evaluated the utility of QDFM for the large-scale physical mapping of a rather unstable, repeat-rich 850-kb region encompassing the immunoglobulin λ variant (IGLV) gene segments. We mapped a minimal tiling path composed of 32 cosmid clones to three partially overlapping yeast artificial chromosome (YAC) clones and determined the physical size of each clone, the extent of overlap between clones, and contig orientation, as well as the sizes of gaps between adjacent contigs. Regions of germline DNA for which we had no YAC coverage were characterized by cosmid to cosmid hybridizations. Compared to other methods commonly used for physical map assembly, QDFM is a rapid, versatile technique delivering unambiguous data necessary for map closure and preparation of sequence-ready minimal tiling paths.     

Thioredoxin-independent Regulation of Metabolism by the ��-Arrestin Proteins

Thioredoxin-interacting protein (Txnip), originally characterized as an inhibitor of thioredoxin, is now known to be a critical regulator of glucose metabolism in vivo. Txnip is a member of the α-arrestin protein family; the α-arrestins are related to the classical β-arrestins and visual arrestins. Txnip is the only α-arrestin known to bind thioredoxin, and it is not known whether the metabolic effects of Txnip are related to its ability to bind thioredoxin or related to conserved α-arrestin function. Here we show that wild type Txnip and Txnip C247S, a Txnip mutant that does not bind thioredoxin in vitro, both inhibit glucose uptake in mature adipocytes and in primary skin fibroblasts. Furthermore, we show that Txnip C247S does not bind thioredoxin in cells, using thiol alkylation to trap the Txnip-thioredoxin complex. Because Txnip function was independent of thioredoxin binding, we tested whether inhibition of glucose uptake was conserved in the related α-arrestins Arrdc4 and Arrdc3. Both Txnip and Arrdc4 inhibited glucose uptake and lactate output, while Arrdc3 had no effect. Structure-function analysis indicated that Txnip and Arrdc4 inhibit glucose uptake independent of the C-terminal WW-domain binding motifs, recently identified as important in yeast α-arrestins. Instead, regulation of glucose uptake was intrinsic to the arrestin domains themselves. These data demonstrate that Txnip regulates cellular metabolism independent of its binding to thioredoxin and reveal the arrestin domains as crucial structural elements in metabolic functions of α-arrestin proteins.Thioredoxin-interacting protein (Txnip),³ an inhibitor of thioredoxin disulfide reductase activity in vitro (1–3), is robustly induced by glucose (4–6) and a critical regulator of metabolism in vivo (7–10). In humans, Txnip expression is suppressed by insulin and strongly up-regulated in diabetes (7). Txnip-deficient mice have fasting hypoglycemia and ketosis (8, 9, 11, 12) with a striking enhancement of glucose uptake by peripheral tissues (8, 9). We have proposed that Txnip inhibits thioredoxin by forming a mixed disulfide with thioredoxin at its catalytic active site cysteines in a disulfide exchange reaction (13). However, it is not known how Txnip metabolic functions relate to its ability to bind thioredoxin.Structurally, Txnip belongs to the arrestin superfamily of proteins (14). The prototypical arrestins (the visual arrestins and the β-arrestins) are key regulators of receptor signaling. The β-arrestins, named for their interaction with the β-adrenergic receptor, are now known to control signaling through the multiple families of receptors (15). These arrestin proteins have two wing-like arrestin domains arranged around a central core that detects and binds selectively to the charged phosphates of activated receptors (16). The arrestin domains then act as multifunctional scaffolds that cannot only quench receptor signals by recruiting endocytotic machinery and ubiquitin ligases, but also start new signal cascades (15). Recently, arrestin-β2 has also been shown to play a key role in metabolism as a controller of insulin receptor signaling that is deficient in diabetes (17).In addition to the classical visual/β-arrestins, a large number of arrestins more closely related to Txnip are present throughout multicellular evolution. These proteins have been termed the “α-arrestins,” as they are of more ancient origin than the visual/β family (14). Although no structures are known of the α-arrestins to date, they appear highly likely to share the overall fold: two β-sheet sandwich arrestin domains connected by a short linker sequence (14, 18). Confidence in this prediction has been enhanced by the surprising finding that the vps26 family of proteins, even more distantly related to the classical arrestins than Txnip, also share the arrestin fold (19). The vps26 proteins are a component of the retromer complex that controls retrograde transport of recycling endosomes to the trans-Golgi network. This functional overlap with visual/β-arrestin regulation of endocytosis suggests that control of endosome formation and transport may be a conserved function of the arrestin superfamily fold.The functions of the mammalian α-arrestins remain unclear. Humans have six α-arrestins: Txnip and five other proteins, which have been assigned the names Arrdc1–5 (arrestin domain-containing 1–5) (13). Very little is known about these other α-arrestins; thioredoxin binding is not conserved beyond Txnip (13, 20). More is known in yeast: recent reports suggest that α-arrestins function in regulation of endocytosis and protein ubiquitination through PXXY motifs in their C-terminal tails (21–25). However, as all the vertebrate α-arrestins have diverged from the ancestral α-arrestins (14), their structure-function relationships may differ from yeast α-arrestins.Given that other α-arrestins are not thioredoxin-binding proteins, we hypothesized that Txnip metabolic functions may be conserved in mammalian α-arrestins and independent of its interaction with thioredoxin. Overexpression of Txnip in vitro can decrease levels of available thioredoxin and increase levels of reactive oxygen species (1, 3, 26). However, in vivo studies of two different Txnip-deficient mouse models found no change in available thioredoxin levels (8, 27). Txnip reportedly binds to other proteins including Jab1 (28) and Dnajb5 (29), but it is not clear to what extent these interactions are themselves independent of a Txnip-thioredoxin complex (30).Using overexpression of a mutant Txnip that does not bind thioredoxin, we show here that a major metabolic function of Txnip, its inhibition of glucose uptake, does not require interaction with thioredoxin. Instead, we show that inhibition of glucose uptake is a conserved function of another human α-arrestin, Arrdc4. Studies of Txnip mutants and chimeric α-arrestins suggest that the metabolic functions of Txnip and Arrdc4 are intrinsic to the arrestin domains.     

Regulation of amyloid-β production by the prion protein

Alzheimer disease (AD) is characterized by the amyloidogenic processing of the amyloid precursor protein (APP), culminating in the accumulation of amyloid-β peptides in the brain. The enzymatic action of the β-secretase, BACE1 is the rate-limiting step in this amyloidogenic processing of APP. BACE1 cleavage of wild-type APP (APP_WT) is inhibited by the cellular prion protein (PrP^C). Our recent study has revealed the molecular and cellular mechanisms behind this observation by showing that PrP^C directly interacts with the pro-domain of BACE1 in the trans-Golgi network (TGN), decreasing the amount of BACE1 at the cell surface and in endosomes where it cleaves APP_WT, while increasing BACE1 in the TGN where it preferentially cleaves APP with the Swedish mutation (APP_Swe). PrP^C deletion in transgenic mice expressing the Swedish and Indiana familial mutations (APP_Swe,Ind) failed to affect amyloid-β accumulation, which is explained by the differential subcellular sites of action of BACE1 toward APP_WT and APP_Swe. This, together with our observation that PrP^C is reduced in sporadic but not familial AD brain, suggests that PrP^C plays a key protective role against sporadic AD. It also highlights the need for an APP_WT transgenic mouse model to understand the molecular and cellular mechanisms underlying sporadic AD.     

Regulation of amyloid-β production by the prion protein

Alzheimer disease (AD) is characterized by the amyloidogenic processing of the amyloid precursor protein (APP), culminating in the accumulation of amyloid-β peptides in the brain. The enzymatic action of the β-secretase, BACE1 is the rate-limiting step in this amyloidogenic processing of APP. BACE1 cleavage of wild-type APP (APP_WT) is inhibited by the cellular prion protein (PrP^C). Our recent study has revealed the molecular and cellular mechanisms behind this observation by showing that PrP^C directly interacts with the pro-domain of BACE1 in the trans-Golgi network (TGN), decreasing the amount of BACE1 at the cell surface and in endosomes where it cleaves APP_WT, while increasing BACE1 in the TGN where it preferentially cleaves APP with the Swedish mutation (APP_Swe). PrP^C deletion in transgenic mice expressing the Swedish and Indiana familial mutations (APP_Swe,Ind) failed to affect amyloid-β accumulation, which is explained by the differential subcellular sites of action of BACE1 toward APP_WT and APP_Swe. This, together with our observation that PrP^C is reduced in sporadic but not familial AD brain, suggests that PrP^C plays a key protective role against sporadic AD. It also highlights the need for an APP_WT transgenic mouse model to understand the molecular and cellular mechanisms underlying sporadic AD.     

Transcriptional Regulation of Cannabinoid Receptor-1 Expression in the Liver by Retinoic Acid Acting via Retinoic Acid Receptor-γ

Alcoholism can result in fatty liver that can progress to steatohepatitis, cirrhosis, and liver cancer. Mice fed alcohol develop fatty liver through endocannabinoid activation of hepatic CB₁ cannabinoid receptors (CB₁R), which increases lipogenesis and decreases fatty acid oxidation. Chronic alcohol feeding also up-regulates CB₁R in hepatocytes in vivo, which could be replicated in vitro by co-culturing control hepatocytes with hepatic stellate cells (HSC) isolated from ethanol-fed mice, implicating HSC-derived mediator(s) in the regulation of hepatic CB₁R (Jeong, W. I., Osei-Hyiaman, D., Park, O., Liu, J., Bátkai, S., Mukhopadhyay, P., Horiguchi, N., Harvey-White, J., Marsicano, G., Lutz, B., Gao, B., and Kunos, G. (2008) Cell Metab. 7, 227–235). HSC being a rich source of retinoic acid (RA), we tested whether RA and its receptors may regulate CB₁R expression in cultured mouse hepatocytes. Incubation of hepatocytes with RA or RA receptor (RAR) agonists increased CB₁R mRNA and protein, the most efficacious being the RARγ agonist CD437 and the pan-RAR agonist TTNPB. The endocannabinoid 2-arachidonoylglycerol (2-AG) also increased hepatic CB₁R expression, which was mediated indirectly via RA, because it was absent in hepatocytes from mice lacking retinaldehyde dehydrogenase 1, the enzyme catalyzing the generation of RA from retinaldehyde. The binding of RARγ to the CB₁R gene 5′ upstream domain in hepatocytes treated with RAR agonists or 2-AG was confirmed by chromatin immunoprecipitation and electrophoretic mobility shift and antibody supershift assays. Finally, TTNPB-induced CB₁R expression was attenuated by small interfering RNA knockdown of RARγ in hepatocytes. We conclude that RARγ regulates CB₁R expression and is thus involved in the control of hepatic fat metabolism by endocannabinoids.