Investigation of the spatial structure and interactions of the genome at sub-kilobase-pair resolution using T2C.

Chromosome conformation capture (3C) and its derivatives (e.g., 4C, 5C and Hi-C) are used to analyze the 3D organization of genomes. We recently developed targeted chromatin capture (T2C), an inexpensive method for studying the 3D organization of genomes, interactomes and structural changes associated with gene regulation, the cell cycle, and cell survival and development. Here, we present the protocol for T2C based on capture, describing all experimental steps and bio-informatic tools in full detail. T2C offers high resolution, a large dynamic interaction frequency range and a high signal-to-noise ratio. Its resolution is determined by the resulting fragment size of the chosen restriction enzyme, which can lead to sub-kilobase-pair resolution. T2C's high coverage allows the identification of the interactome of each individual DNA fragment, which makes binning of reads (often used in other methods) basically unnecessary. Notably, T2C requires low sequencing efforts. T2C also allows multiplexing of samples for the direct comparison of multiple samples. It can be used to study topologically associating domains (TADs), determining their position, shape, boundaries, and intra- and inter-domain interactions, as well as the composition of aggregated loops, interactions between nucleosomes, individual transcription factor binding sites, and promoters and enhancers. T2C can be performed by any investigator with basic skills in molecular biology techniques in ∼7-8 d. Data analysis requires basic expertise in bioinformatics and in Linux and Python environments.

The detailed 3D multi-loop aggregate/rosette chromatin architecture and functional dynamic organization of the human and mouse genomes.

BACKGROUND: The dynamic three-dimensional chromatin architecture of genomes and its co-evolutionary connection to its function-the storage, expression, and replication of genetic information-is still one of the central issues in biology. Here, we describe the much debated 3D architecture of the human and mouse genomes from the nucleosomal to the megabase pair level by a novel approach combining selective high-throughput high-resolution chromosomal interaction capture (T2C), polymer simulations, and scaling analysis of the 3D architecture and the DNA sequence. RESULTS: The genome is compacted into a chromatin quasi-fibre with ~5 ± 1 nucleosomes/11 nm, folded into stable ~30-100 kbp loops forming stable loop aggregates/rosettes connected by similar sized linkers. Minor but significant variations in the architecture are seen between cell types and functional states. The architecture and the DNA sequence show very similar fine-structured multi-scaling behaviour confirming their co-evolution and the above. CONCLUSIONS: This architecture, its dynamics, and accessibility, balance stability and flexibility ensuring genome integrity and variation enabling gene expression/regulation by self-organization of (in)active units already in proximity. Our results agree with the heuristics of the field and allow "architectural sequencing" at a genome mechanics level to understand the inseparable systems genomic properties.

Sample entropy predicts lifesaving interventions in trauma patients with normal vital signs.

INTRODUCTION: Heart rate complexity, commonly described as a "new vital sign," has shown promise in predicting injury severity, but its use in clinical practice is not yet widely adopted. We previously demonstrated the ability of this noninvasive technology to predict lifesaving interventions (LSIs) in trauma patients. This study was conducted to prospectively evaluate the utility of real-time, automated, noninvasive, instantaneous sample entropy (SampEn) analysis to predict the need for an LSI in a trauma alert population presenting with normal vital signs. METHODS: Prospective enrollment of patients who met criteria for trauma team activation and presented with normal vital signs was conducted at a level I trauma center. High-fidelity electrocardiogram recording was used to calculate SampEn and SD of the normal-to-normal R-R interval (SDNN) continuously in real time for 2 hours with a portable, handheld device. Patients who received an LSI were compared to patients without any intervention (non-LSI). Multivariable analysis was performed to control for differences between the groups. Treating clinicians were blinded to results. RESULTS: Of 129 patients enrolled, 38 (29%) received 136 LSIs within 24 hours of hospital arrival. Initial systolic blood pressure was similar in both groups. Lifesaving intervention patients had a lower Glasgow Coma Scale. The mean SampEn on presentation was 0.7 (0.4-1.2) in the LSI group compared to 1.5 (1.1-2.0) in the non-LSI group (P < .0001). The area under the curve with initial SampEn alone was 0.73 (95% confidence interval [CI], 0.64-0.81) and increased to 0.93 (95% CI, 0.89-0.98) after adding sedation to the model. Sample entropy of less than 0.8 yields sensitivity, specificity, negative predictive value, and positive predictive value of 58%, 86%, 82%, and 65%, respectively, with an overall accuracy of 76% for predicting an LSI. SD of the normal-to-normal R-R interval had no predictive value. CONCLUSIONS: In trauma patients with normal presenting vital signs, decreased SampEn is an independent predictor of the need for LSI. Real-time SampEn analysis may be a useful adjunct to standard vital signs monitoring. Adoption of real-time, instantaneous SampEn monitoring for trauma patients, especially in resource-constrained environments, should be considered.

cAMP response element-binding protein 1 is required for hydroxyurea-mediated induction of γ-globin expression in K562 cells.

1. Hydroxyurea (HU) is a drug used for the treatment of haemoglobinopathies. Hydroxyurea functions by upregulating γ-globin transcription and fetal haemoglobin (HbF) production in erythroid cells. The K562 erythroleukaemia cell line is widely used as a model system in which to study the mechanism of γ-globin induction by HU. However, the transcription factors required for the upregulation of γ-globin expression by HU in K562 cells have not been identified. Similarities between the HU and sodium butyrate (SB) pathways suggest cAMP response element-binding protein (CREB) 1 as a potential candidate. Thus, the aim of the present study was to investigate the possible role of CREB1 in the HU pathway. 2. Experiments were performed using transient and stable RNA interference (RNAi) to show that CREB1 is necessary for HU-mediated induction of γ-globin expression and haemoglobin production in K562 cells. 3. Furthermore, western blot analyses demonstrated that CREB1 becomes phosphorylated in a dose-dependent manner after HU (100-400 µmol/L) treatment of K562 cells for 72 h. 4. We also investigated role of a Gγ promoter CREB1 response element (G-CRE) in this pathway. Quantitative amplification refractory mutation system-polymerase chain reaction experiments were performed to demonstrate that HU induces the expression of both Gγ and Aγ in this cell line. In addition, electrophoretic mobility shift assays were used to show that levels of CREB1 complexes binding to the G-CRE site are increased following HU treatment and are decreased in CREB1-knockdown cells. 5. The results suggest that CREB1 is necessary for γ-globin induction by HU in K562 cells, a role that may be mediated, in part, through the G-CRE element.

Multiple interactions between regulatory regions are required to stabilize an active chromatin hub.

The human beta-globin locus control region (LCR) is required for the maintenance of an open chromatin configuration of the locus. It interacts with the genes and the hypersensitive regions flanking the locus to form an active chromatin hub (ACH) transcribing the genes. Proper developmental control of globin genes is largely determined by gene proximal regulatory sequences. Here, we provide the first functional evidence of the role of the most active sites of the LCR and the promoter of the beta-globin gene in the maintenance of the ACH. When the human beta-globin gene promoter is deleted in the context of a full LCR, the ACH is maintained with the beta-globin gene remaining in proximity. Additional deletion of hypersensitive site HS3 or HS2 of the LCR shows that HS3, but not HS2, in combination with the beta-globin promoter is crucial for the maintenance of the ACH at the definitive stage. We conclude that multiple interactions between the LCR and the beta-globin gene are required to maintain the appropriate spatial configuration in vivo.

An embryonic-specific repressor element located 3' to the Agamma-globin gene influences transcription of the human beta-globin locus in transgenic mice.

OBJECTIVE: Persistent expression of the human fetal gamma-globin genes in the adult stage is often associated with naturally occurring deletions in the human beta-globin locus. The mapping of the 5' breakpoints of these deletions within the Agamma- to delta-globin intergenic region has suggested that regulatory elements involved in the silencing of the gamma-globin genes in the adult may be present. We previously identified two elements in this region, termed Enh and F, located 3' to the Agamma-globin gene acting as silencers in transient transfection assays. Here, we tested directly the in vivo significance of these elements in the developmental regulation of the human beta-like globin genes. MATERIALS AND METHODS. We selectively deleted both Enh and F elements in the context of a 185-kb human beta-globin locus PAC (P1 phage artificial chromosome) and tested the effects of this deletion on the expression of the human P-like globin genes in transgenic mice. RESULTS: The Enh/F deletion resulted in an increase in epsilon- and gamma-globin mRNA levels in the embryonic yolk sac stage of erythropoiesis, which appears to be due to an increase in the rate of transcription rather than to an increase in the number of cells transcribing the human globin locus. However, the human developmental switching from fetal gamma-globin to adult beta-globin gene expression in transgenic mice was not affected by this deletion. CONCLUSION: These results identify Enh and F as locus-wide regulatory elements capable of down-regulating transcription of the human beta-globin locus in an embryonic-specific manner.

The role of the -50 region of the human gamma-globin gene in switching.

During the switch from human gamma- (fetal) to beta- (adult) globin gene expression, the gamma and beta genes are expressed competitively by an alternating transcription mechanism. The -50 region of the gamma gene promoter has been proposed to be responsible for the early competitive advantage of the gamma genes and to act as a stage selector element (SSE) in hemoglobin switching. We analyzed the effect of mutating the -50 region of the gamma gene in the presence of a competing beta gene in transgenic mice. This shows that the -50 region does not affect silencing of the beta gene in early development and does not act as a stage selector. However, it affects the ratio of gamma versus beta gene expression in the early, but not later, stages of fetal development. Interestingly, both the wild-type and mutant minilocus constructs show a higher frequency of alternate transcription than observed in the complete locus, suggesting that sequences normally present between the gamma and beta genes facilitate the interaction of the locus control region (LCR) and beta-globin gene in the complete locus.

Modification of human beta-globin locus PAC clones by homologous recombination in Escherichia coli.

We report here modifications of human beta-globin PAC clones by homologous recombination in Escherichia coli DH10B, utilising a plasmid temperature sensitive for replication, the recA gene and a wild-type copy of the rpsL gene which allows for an efficient selection for plasmid loss in this host. High frequencies of recombination are observed even with very small lengths of homology and the method has general utility for introducing insertions, deletions and point mutations. No rearrangements were detected with the exception of one highly repetitive genomic sequence when either the E.COLI: RecA- or the lambdoid phage encoded RecT and RecE-dependent recombination systems were used.

Cutaneous myiasis due to Dermatobia hominis in Saudis.

Cutaneous myiasis infestations are normally found in South and Central America but increasing travel has resulted in their spread to non-indigenous countries with increasing frequency. We report two cases of cutaneous infestation by Dermatobia hominis in Taif, Saudi Arabia. There was no history of travel outside Saudi Arabia. The source of infection appears to be domestic cattle indicating that these infestations may be endemic in this region.

Transcription factors induced by interferons alpha and gamma.

Factors induced by interferons (IFNs) bind to the IFN-stimulated response elements (ISREs) of many genes. In human cells treated with type I (alpha, beta) IFN, factor E is induced in about 1 min and factor M after about 1 hr. Factor G is induced after about 1 hr in cells treated with type II (gamma) IFN. G and M have very similar positions in bandshift assays, sensitivities to cycloheximide, footprints on an ISRE and relative affinities for different ISREs. Four different patterns of expression were observed in different cell lines: E,M and G strongly induced; M and G strongly but E weakly; only E and M induced; only E induced. Transcription in response to IFN alpha is initiated by E and probably maintained by M since, in fibroblasts, M is present maximally when transcription is most active and declines together with transcription. In Bristol-8 cells, where induction of M is not detected, transcription is still induced by IFN alpha and still declines in its continued presence, suggesting that M is not essential for either process. A variant ISRE with two G-to-C mutations binds E especially weakly but M and G strongly. The mutations don't change the response of a reporter gene to IFN gamma but do abolish its response to IFN alpha, suggesting that the binding of M is not sufficient for the latter. G probably acts positively, since its appearance correlates well with induction of transcription by IFN gamma. A 39-bp ISRE from the 9-27 gene binds E much better than M or G. Conversely, a 39-bp ISRE from the 6-16 gene binds M and G much better than E. Different patterns of expression of E, M, and G and different affinities of these factors for alternative ISREs may play a part in modulating the relative responses of genes to type I and type II IFNs in vivo.

Rapid activation by interferon alpha of a latent DNA-binding protein present in the cytoplasm of untreated cells.

The highly conserved interferon (IFN)-stimulated regulatory elements of the human genes 6-16 and 9-27 bind to one or more proteins (E factor) detected in extracts of human Bristol 8 B cells or human foreskin fibroblast cells treated with IFN-alpha. E factor is not detectable in extracts of untreated cells and appears in IFN-treated cells within less than 1 min in a form extractable with low salt and thus presumably not bound to DNA. After a few more minutes, the level of this form decreases in parallel with the increase of a form extractable only with high salt and thus presumably bound to DNA. Induction of E factor by IFN-alpha can occur in nuclei-free cytoplasts, whereas no E factor was detected in IFN-treated nucleoplasts. Together, these results suggest a model for signal transduction in which latent E factor, located in the cytoplasm, is activated or released from an inhibitor very rapidly upon binding of IFN-alpha to its receptor. Active E factor can then migrate to the nucleus, where it binds to the IFN-stimulated regulatory elements of IFN-regulated genes, activating their transcription.

Analysis of thymidylate synthase gene amplification and of mRNA levels in the cell cycle.

We report that the gene for thymidylate synthase (TS) is amplified in the mouse cell line L1210:C15 that was selectively grown in increasing concentrations of the competitive inhibitor of thymidylate synthase, CB3717. The gene is amplified 50-fold compared to the parental cell line. Amplification has not been accompanied by any major rearrangements, and the increase in gene copy number is reflected in elevation of thymidylate synthase mRNA levels. The amplification is relatively stable as there was only a 2- to 3-fold decrease in the number of amplified TS genes when cells were grown in the absence of selection for 375 generations. We also observe a 30- to 40-fold increase in number of copies of the dihydrofolate reductase gene with 7-fold elevation of the RNA product, and we suggest that this may be due to cross-inhibition of dihydrofolate reductase by CB3717. Thymidylate synthase mRNA levels in L1210 and L1210:C15 show no variation within the different phases of the cell cycle but are significantly reduced during quiescence.

The identification of a DNA polymorphism of the alpha fibrinogen gene, and the regional assignment of the human fibrinogen genes to 4q26-qter.

We have identified a common restriction fragment length polymorphism of the alpha fibrinogen gene with the enzyme TaqI. This polymorphism is probably due to a single base change that creates or destroys a TaqI recognition site about 1000 basepairs from the 3' end of the alpha fibrinogen géne. The frequency of the rare allele in 83 unrelated healthy individuals is 0.33. We have used in situ hybridisation of the alpha fibrinogen cDNA to localise the gene on chromosome 4q29-31. We have confirmed this regional localisation by restriction fragment detection in a human X Chinese hamster somatic cell hybrid which contains a translocated human chromosome 4 with a breakpoint at 4q26. The alpha, beta, and gamma fibrinogen genes are all present on human chromosome 4q26-qter.

Isolation and characterisation of cDNA clones for the A alpha- and gamma-chains of human fibrinogen.

cDNA clones coding for the A alpha- and gamma-chains of human fibrinogen have been isolated from an adult liver cDNA library. Clones were identified by hybridisation with mixtures of synthetic oligonucleotides 17 bases long, predicted using amino acid sequence data for each chain. The cDNA insert sizes are 1,950bp for A alpha-fibrinogen and 950bp for gamma-fibrinogen. The clones do not show any cross-hybridisation. Each cDNA hybridises to a unique sequence in the human genome. In adult human liver, Northern blots give an estimated messenger RNA size of 2.6kb for A alpha-fibrinogen and 1.8kb for gamma-fibrinogen.