High-resolution TADs reveal DNA sequences underlying genome organization in flies

Ramírez, Fidel; Bhardwaj, Vivek; Arrigoni, Laura; Lam, Kin Chung; Grüning, Björn; Villaveces, José; Habermann, Bianca; Akhtar, Asifa; Manke, Thomas

doi:10.1038/s41467-017-02525-w

Cited by 691 publications

(762 citation statements)

References 71 publications

Supporting

Mentioning

702

Contrasting

Unclassified

Order By: Relevance

“…Whereas the lack of CTCF is embryonic lethal in mammals, in Drosophila CTCF null mutants (completely lacking both maternal and zygotic CTCF) survive past the larval stage and die as late pupae with visible defects associated with Hox gene misexpression . Although Drosophila CTCF is clearly linked to functional regulatory domains in the Hox complexes, it is generally only weakly enriched at TAD boundaries . A recent paper suggests that CTCF may have a specific role in certain differentiated cell types as this study found a stronger enrichment of CTCF at TAD borders in a cell line derived from larval central nervous system than in Kc167 cells originally derived from embryos .…”

Section: How Is Domain Architecture Established Across Different Orgamentioning

confidence: 50%

“…A recent paper suggests that CTCF may have a specific role in certain differentiated cell types as this study found a stronger enrichment of CTCF at TAD borders in a cell line derived from larval central nervous system than in Kc167 cells originally derived from embryos . In addition to CTCF, Drosophila contains a number of less‐conserved insulator binding proteins, such as Chromator and boundary element associated factor of 32 kD (BEAF‐32), that are much more highly enriched at TAD boundaries and appear to serve a more general architectural function …”

Section: How Is Domain Architecture Established Across Different Orgamentioning

confidence: 63%

“… Drosophila interaction domain profile. a) A 2 Mb region (chrom2L: 10 000 000–12 000 000) illustrating the correspondence between interaction profile and chromatin domain maps; D (green)/E (blue) domains, originally derived from primary spermatocyte data, A (green)/ B (blue) compartments from Kc167 cells, Kc167 cell Hi‐C interaction profile from Ramírez et al b) Portion of Drosophila polytene chromosome showing bands and interbands. Image reproduced with permission from Cell Image Library doi:10.7295/W9CIL25393.…”

Section: Recent Experimental Results From Drosophila Give Fresh Insightmentioning

confidence: 99%

“…This figure also illustrates different TAD hierarchies; the large TAD on the right, comprising an A compartment region, is further subdivided into minidomains (see Section and Figure ), whilst the large TAD on the left shows at least three levels of progressively larger domains, encompassing both A and B compartment regions. Hi‐C from Kc167 cells, A compartments from Kc167 cells, BEAF‐32 ChIP from Kc167 cells (ModENCODE GSM1535963), housekeeping genes from El‐Sharnouby et al and the FISH probe from Szabo et al ChIP, chromatin immunoprecipitation.…”

Section: Recent Experimental Results From Drosophila Give Fresh Insightmentioning

confidence: 99%

“…Insulators have long been proposed as major determinants of the regulatory architecture of the genome . Although binding profiles of architectural proteins such as Chromator, BEAF‐32, and Z4/Putzig show a strong correlation with domain architecture, only BEAF‐32 has been directly tested for a role in domain organization . Knockdown of BEAF‐32 by RNA interference in Drosophila S2 cells showed no change in the global Hi‐C interaction profile.…”

Section: Recent Experimental Results From Drosophila Give Fresh Insightmentioning

confidence: 99%

See 4 more Smart Citations

Chromatin Architecture in the Fly: Living without CTCF/Cohesin Loop Extrusion?

Matthews

White

2019

BioEssays

View full text Add to dashboard Cite

The organization of the genome into topologically associated domains (TADs) appears to be a fundamental process occurring across a wide range of eukaryote organisms, and it likely plays an important role in providing an architectural foundation for gene regulation. Initial studies emphasized the remarkable parallels between TAD organization in organisms as diverse as Drosophila and mammals. However, whereas CCCTC‐binding factor (CTCF)/cohesin loop extrusion is emerging as a key mechanism for the formation of mammalian topological domains, the genome organization in Drosophila appears to depend primarily on the partitioning of chromatin state domains. Recent work suggesting a fundamental conserved role of chromatin state in building domain architecture is discussed and insights into genome organization from recent studies in Drosophila are considered.

show abstract

Section: How Is Domain Architecture Established Across Different Orgamentioning

confidence: 50%

Section: How Is Domain Architecture Established Across Different Orgamentioning

confidence: 63%

Section: Recent Experimental Results From Drosophila Give Fresh Insightmentioning

confidence: 99%

Section: Recent Experimental Results From Drosophila Give Fresh Insightmentioning

confidence: 99%

Section: Recent Experimental Results From Drosophila Give Fresh Insightmentioning

confidence: 99%

See 3 more Smart Citations

Chromatin Architecture in the Fly: Living without CTCF/Cohesin Loop Extrusion?

Matthews

White

2019

BioEssays

View full text Add to dashboard Cite

show abstract

CD38‐Specific CAR Integrated into CD38 Locus Driven by Different Promoters Causes Distinct Antitumor Activities of T and NK Cells

et al. 2023

View full text Add to dashboard Cite

The robust and stable expression of CD38 in T‐cell acute lymphoblastic leukemia (T‐ALL) blasts makes CD38 chimeric antigen receptor (CAR)‐T/natural killer (NK) a potential therapy for T‐ALL. However, CD38 expression in normal T/NK cells causes fratricide of CD38 CAR‐T/NK cells. Here a “2‐in‐1” gene editing strategy is developed to generate fratricide‐resistant locus‐specific CAR‐T/NK cells. CD38‐specific CAR is integrated into the disrupted CD38 locus by CRISPR/Cas9, and CAR is placed under the control of either endogenous CD38 promoter (CD38KO/KI) or exogenous EF1α promoter (CD38KO/KIEF1α). CD38 knockout reduces fratricide and allows the expansion of CAR‐T cells. Meanwhile, CD38KO/KIEF1α results in higher CAR expression than CD38KO/KI in both CAR‐T and CAR‐NK cells. In a mouse T‐ALL model, CD38KO/KIEF1α CAR‐T cells eradicate tumors better than CD38KO/KI CAR‐T cells. Surprisingly, CD38KO/KI CAR‐NK cells show superior tumor control than CD38KO/KIEF1α CAR‐NK cells. Further investigation reveals that endogenous regulatory elements in NK cells lead to higher expression of CD38 CAR than in T cells, and the expression levels of CAR affect the therapeutic outcome of CAR‐T and CAR‐NK cells differently. Therefore, these results support the efficacy of CD38 CAR‐T/NK against T‐ALL and demonstrate that the “2‐in‐1” strategy can resolve fratricide and enhance tumor eradication, paving the way for clinical translation.

show abstract

BHLHE40 Inhibits Ferroptosis in Pancreatic Cancer Cells via Upregulating SREBF1

Cao,

Wang,

Liu

et al. 2023

Advanced Science

View full text Add to dashboard Cite

Pancreatic cancer (PCa) is one of the most fatal human malignancies. The enhanced infiltration of stromal tissue into the PCa tumor microenvironment limits the identification of key tumor‐specific transcription factors and epigenomic abnormalities in malignant epithelial cells. Integrated transcriptome and epigenetic multiomics analyses of the paired PCa organoids indicate that the basic helix‐loop‐helix transcription factor 40 (BHLHE40) is significantly upregulated in tumor samples. Increased chromatin accessibility at the promoter region and enhanced mTOR pathway activity contribute to the elevated expression of BHLHE40. Integrated analysis of chromatin immunoprecipitation‐seq, RNA‐seq, and high‐throughput chromosome conformation capture data, together with chromosome conformation capture assays, indicate that BHLHE40 not only regulates sterol regulatory element‐binding factor 1 (SREBF1) transcription as a classic transcription factor but also links the enhancer and promoter regions of SREBF1. It is found that the BHLHE40‐SREBF1‐stearoyl‐CoA desaturase axis protects PCa cells from ferroptosis, resulting in the reduced accumulation of lipid peroxidation. Moreover, fatostatin, an SREBF1 inhibitor, significantly suppresses the growth of PCa tumors with high expressions of BHLHE40. This study highlights the important roles of BHLHE40‐mediated lipid peroxidation in inducing ferroptosis in PCa cells and provides a novel mechanism underlying SREBF1 overexpression in PCa.

show abstract

High-resolution TADs reveal DNA sequences underlying genome organization in flies

Cited by 691 publications

References 71 publications

Chromatin Architecture in the Fly: Living without CTCF/Cohesin Loop Extrusion?

Chromatin Architecture in the Fly: Living without CTCF/Cohesin Loop Extrusion?

CD38‐Specific CAR Integrated into CD38 Locus Driven by Different Promoters Causes Distinct Antitumor Activities of T and NK Cells

BHLHE40 Inhibits Ferroptosis in Pancreatic Cancer Cells via Upregulating SREBF1

Contact Info

Product

Resources

About