Clonal fate mapping quantifies the number of haematopoietic stem cells that arise during development.

Haematopoietic stem cells (HSCs) arise in the developing aorta during embryogenesis. The number of HSC clones born has been estimated through transplantation, but experimental approaches to assess the absolute number of forming HSCs in a native setting have remained challenging. Here, we applied single-cell and clonal analysis of HSCs in zebrafish to quantify developing HSCs. Targeting creERT2 in developing cd41:eGFP+ HSCs enabled long-term assessment of their blood contribution. We also applied the Brainbow-based multicolour Zebrabow system with drl:creERT2 that is active in early haematopoiesis to induce heritable colour barcoding unique to each HSC and its progeny. Our findings reveal that approximately 21 HSC clones exist prior to HSC emergence and 30 clones are present during peak production from aortic endothelium. Our methods further reveal that stress haematopoiesis, including sublethal irradiation and transplantation, reduces clonal diversity. Our findings provide quantitative insights into the early clonal events that regulate haematopoietic development.

Maleimide-based method for elaboration of cysteine-containing peptide phage libraries.

Peptide-based molecules are known to have therapeutic utility, but the generation of phage-focused libraries to optimize peptide properties and functionality is challenging. Genetic approaches are limited to peptide extension on the peptide termini. Current chemical methods are technically challenging and time-consuming. A new chemical method is developed to extend a maleimide-conjugated peptide with a cysteine-containing random peptide phage display library. As a proof of concept, a 15-mer epidermal growth factor receptor (EGFR)-binding peptide was synthesized with a maleimide group at its C-terminus and then conjugated to the cysteine-containing library. After panning and screening, several extended peptides were discovered and tested to have a higher affinity to EGFR. This strategy can have broad utility to optimize pharmacophores of any modalities (peptides, unnatural peptides, drug conjugates) capable of bearing a maleimide group.

A simple and efficient maleimide-based approach for peptide extension with a cysteine-containing peptide phage library.

Although peptide-based molecules are known to have therapeutic potential, the generation of phage focused libraries to optimize peptides is effort-consuming. A chemical method is developed to extend a maleimide-conjugated peptide with a cysteine-containing random-peptide phage display library. As a proof of concept, a 15-mer epidermal growth factor receptor (EGFR)-binding peptide was synthesized with a maleimide group at its C-terminus and then conjugated to the cysteine-containing library. After panning and screening, several extended peptides were discovered and tested to have a higher affinity to EGFR. This strategy can have broad utility to optimize pharmacophores of any modalities (peptides, unnatural peptides, drug conjugates) capable of bearing a maleimide group.

Haematopoietic stem cells derive directly from aortic endothelium during development.

A major goal of regenerative medicine is to instruct formation of multipotent, tissue-specific stem cells from induced pluripotent stem cells (iPSCs) for cell replacement therapies. Generation of haematopoietic stem cells (HSCs) from iPSCs or embryonic stem cells (ESCs) is not currently possible, however, necessitating a better understanding of how HSCs normally arise during embryonic development. We previously showed that haematopoiesis occurs through four distinct waves during zebrafish development, with HSCs arising in the final wave in close association with the dorsal aorta. Recent reports have suggested that murine HSCs derive from haemogenic endothelial cells (ECs) lining the aortic floor. Additional in vitro studies have similarly indicated that the haematopoietic progeny of ESCs arise through intermediates with endothelial potential. Here we have used the unique strengths of the zebrafish embryo to image directly the generation of HSCs from the ventral wall of the dorsal aorta. Using combinations of fluorescent reporter transgenes, confocal time-lapse microscopy and flow cytometry, we have identified and isolated the stepwise intermediates as aortic haemogenic endothelium transitions to nascent HSCs. Finally, using a permanent lineage tracing strategy, we demonstrate that the HSCs generated from haemogenic endothelium are the lineal founders of the adult haematopoietic system.

Reconstitution of chromatin transcription with purified components reveals a chromatin-specific repressive activity of p300.

Here we describe an in vitro chromatin transcription system in which chromatin assembly and transcription are carried out with purified and defined factors. With basal (also known as general) transcription factors and sequence-specific DNA-binding activators, we observed chromatin-specific, activation domain-dependent transcription. We then examined the biochemical function of purified p300 in the absence of the endogenous factor and other related activities and found, unexpectedly, that p300 has a chromatin-specific, transcriptional repression activity that can be relieved by the addition of acetyl-CoA. This p300-mediated repression is reversible, requires the p300 bromodomain but not the acetyltransferase region, and does not involve the formation of a stable, nuclease-resistant nucleoprotein complex. Hence, the mechanism of transcriptional repression by p300 is distinct from that of histone H1, PARP-1 or Sir2. These findings reveal a novel chromatin-specific repressive function of p300.

The MTE, a new core promoter element for transcription by RNA polymerase II.

The core promoter is the ultimate target of the vast network of regulatory factors that contribute to the initiation of transcription by RNA polymerase II. Here we describe the MTE (motif ten element), a new core promoter element that appears to be conserved from Drosophila to humans. The MTE promotes transcription by RNA polymerase II when it is located precisely at positions +18 to +27 relative to A(+1) in the initiator (Inr) element. MTE sequences from +18 to +22 relative to A(+1) are important for basal transcription, and a region from +18 to +27 is sufficient to confer MTE activity to heterologous core promoters. The MTE requires the Inr, but functions independently of the TATA-box and DPE. Notably, the loss of transcriptional activity upon mutation of a TATA-box or DPE can be compensated by the addition of an MTE. In addition, the MTE exhibits strong synergism with the TATA-box as well as the DPE. These findings indicate that the MTE is a novel downstream core promoter element that is important for transcription by RNA polymerase II.