The scarcity of donor organs may be addressed in the future by using pigs to grow humanized organs with lower potential for immunological rejection after transplantation in humans. Previous studies ...have demonstrated that interspecies complementation of rodent blastocysts lacking a developmental regulatory gene can generate xenogeneic pancreas and kidney
. However, such organs contain host endothelium, a source of immune rejection. We used gene editing and somatic cell nuclear transfer to engineer porcine embryos deficient in ETV2, a master regulator of hematoendothelial lineages
. ETV2-null pig embryos lacked hematoendothelial lineages and were embryonic lethal. Blastocyst complementation with wild-type porcine blastomeres generated viable chimeric embryos whose hematoendothelial cells were entirely donor-derived. ETV2-null blastocysts were injected with human induced pluripotent stem cells (hiPSCs) or hiPSCs overexpressing the antiapoptotic factor BCL2, transferred to synchronized gilts and analyzed between embryonic day 17 and embryonic day 18. In these embryos, all endothelial cells were of human origin.
The mammalian heart has a limited regenerative capacity and typically progresses to heart failure following injury. Here, we defined a hedgehog (HH)-Gli1-Mycn network for cardiomyocyte proliferation ...and heart regeneration from amphibians to mammals. Using a genome-wide screen, we verified that HH signaling was essential for heart regeneration in the injured newt. Next, pharmacological and genetic loss- and gain-of-function of HH signaling demonstrated the essential requirement for HH signaling in the neonatal, adolescent, and adult mouse heart regeneration, and in the proliferation of hiPSC-derived cardiomyocytes. Fate-mapping and molecular biological studies revealed that HH signaling, via a HH-Gli1-Mycn network, contributed to heart regeneration by inducing proliferation of pre-existing cardiomyocytes and not by de novo cardiomyogenesis. Further, Mycn mRNA transfection experiments recapitulated the effects of HH signaling and promoted adult cardiomyocyte proliferation. These studies defined an evolutionarily conserved function of HH signaling that may serve as a platform for human regenerative therapies.
Amphibians have a remarkable capacity for limb regeneration. Following a severe injury, there is complete regeneration with restoration of the patterning and cellular architecture of the amputated ...limb. While studies have focused on the structural anatomical changes during amphibian limb regeneration, the signaling mechanisms that govern cellular dedifferentiation and blastemal progenitors are unknown. Here, we demonstrate the temporal and spatial requirement for hedgehog (Hh) signaling and its hierarchical correlation with respect to Wnt signaling during newt limb regeneration. While the dedifferentiation process of mature lineages does not depend on Hh signaling, the proliferation and the migration of the dedifferentiated cells are dependent on Hh signaling. Temporally controlled chemical inactivation of the Hh pathway indicates that Hh-mediated antero-posterior (AP) specification occurs early during limb regeneration and that Hh is subsequently required for expansion of the blastemal progenitors. Inhibition of Hh signaling results in G0/G1 arrest with a concomitant reduction in S-phase and G2/M population in myogenic progenitors. Furthermore, Hh inhibition leads to reduced Pax7-positive cells and fewer regenerating fibers relative to control tissue. We demonstrate that activation of Wnt signaling rescues the inhibition of Hh pathway mainly by enhancing proliferative signals, possibly mediated through TCF4 activity. Collectively, our results demonstrate coordinated signaling of Hh and Wnt activities in regulating blastemal progenitors and their hierarchical positioning during limb regeneration.
► Shh signaling is essential for limb regeneration. ► Reduced Shh signaling does not affect the dedifferentiation process. ► Shh is required for AP patterning at early stages and for cellular expansion at later stages of regeneration. ► Wnt signaling functions downstream of Shh signaling during regeneration.
Because post-mortem human skeletal muscle is not viable, autologous muscle grafts are typically required in tissue reconstruction after muscle loss due to disease or injury. However, the use of ...autologous tissue often leads to donor-site morbidity. Here, we show that intraspecies and interspecies chimaeric pig embryos lacking native skeletal muscle can be produced by deleting the MYF5, MYOD and MYF6 genes in the embryos via CRISPR, followed by somatic-cell nuclear transfer and the delivery of exogenous cells (porcine blastomeres or human induced pluripotent stem cells) via blastocyst complementation. The generated intraspecies chimaeras were viable and displayed normal histology, morphology and function. Human:pig chimaeras generated with TP53-null human induced pluripotent stem cells led to higher chimaerism efficiency, with embryos collected at embryonic days 20 and 27 containing humanized muscle, as confirmed by immunohistochemical and molecular analyses. Human:pig chimaeras may facilitate the production of exogenic organs for research and xenotransplantation.
Regulatory networks that govern embryonic development have been well defined. While a common hypothesis supports the notion that the embryonic regulatory cascades are reexpressed following injury and ...tissue regeneration, the mechanistic regulatory pathways that mediate the regenerative response in higher organisms remain undefined. Relative to mammals, lower vertebrates, including zebrafish and newts, have a tremendous regenerative capacity to repair and regenerate a number of organs including: appendages, retina, heart, jaw and nervous system. Elucidation of the pathways that govern regeneration in these lower organisms may provide cues that will enhance the capacity for the regeneration of mammalian organs. Signaling pathways, such as the hedgehog pathway, have been shown to play critical functions during development and during regeneration in lower organisms. These signaling pathways have been shown to modulate multiple processes including cellular origin, positional identity and cellular maturation. The present review will focus on the cellular and molecular regulation of the hedgehog (HH) signaling pathway and its interaction with other signaling factors during appendage development and regeneration.
Heart of Newt: A Recipe for Regeneration Singh, Bhairab N.; Koyano-Nakagawa, Naoko; Garry, John P. ...
Journal of cardiovascular translational research,
08/2010, Volume:
3, Issue:
4
Journal Article
Peer reviewed
The field of regenerative medicine holds tremendous promise for the treatment of chronic diseases. While the adult mammalian heart has limited regenerative capacity, previous studies have focused on ...cellular therapeutic strategies in an attempt to modulate cardiac regeneration. An alternative strategy relies on the modulation of endogenous stem/progenitor cells or signaling pathways to promote cardiac regeneration. Several organisms, including the newt, have an incomparable capacity for the regeneration of differentiated tissues. An enhanced understanding of the signals, pathways, and factors that mediate the regenerative response in these organisms may be useful in modulating the regenerative response of mammalian organs including the injured adult heart.
Chronic diseases are both common and deadly. Due to the limitations of conventional therapies for chronic diseases such as advanced heart failure and diabetes mellitus, recent interest has been ...directed towards regenerative medicine. In this review, we examine the history of regenerative biology and emphasize the dynamic and multidisciplinary growth of this field. We highlight the spectrum of adult tissues that have a remarkable regenerative capacity (i.e., skeletal muscle) versus those that have a more limited regenerative capacity (i.e., heart). We further emphasize the use of relevant contemporary models for the study of regenerative biology (i.e., pancreatic regeneration), which highlight both the challenges for this field of study and the potential for regenerative medicine, including the use of cell-based strategies, to revolutionize medical therapies for chronic diseases.
Benzene, a well-known human carcinogen, is a commonly used industrial chemical that evokes further toxicological concern because of its potential genotoxic risks as a constituent of petrol and the ...byproduct of combustion and cigarette smoke. The present study investigated the effects of benzene inhalation on the expression of pro- and antiapoptogenic genes in lung epithelia. Immunohistochemical expression was assessed for antiapoptotic Bcl-2 family proteins, including Bcl-2, Bcl-w, and Bag-1 as well as proapoptotic subfamily members with Bcl-2 homology (BH)
1 1–3, namely Bax, those that consist of only the BH3 region, represented by Bad, and proapoptotic gene expression for p53. Rats exposed to benzene via inhalation (300
ppm) for 7 days showed a significant upregulation of proapoptotic gene expression for p53, Bax, and Bad as assessed by a semiquantitative segmental analysis of the lung epithelia, including bronchioles, terminal bronchioles, respiratory bronchioles, and alveoli. Bag-1, an antiapoptogenic gene, was also found to have significant upregulated expression in lung epithelia. Since the underlying mechanisms by which Bag-1 exerts its antiapoptogenic effects are not known, benzene may target the protein chaperones hsc70/hsp70, or RING finger protein associated with Bag-1 activity. Alternatively, the significant downregulation of Bcl-2 may have diminished the antiapoptotic synergism necessary for the effectiveness of Bag-1. Both Bcl-2 and Bcl-w were found to be significantly downregulated compared to the proapoptotic counterparts. These data support the role of benzene in activating proapoptogenic events that lead to the upregulation of gene expression that may provide a crucial defense mechanism within lung parenchyma to reduce mutation hazard and potential carcinogenic effects of benzene-initiated pathogenesis.
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