Abstract
Stimulation of pancreatic beta cell regeneration could be a therapeutic lead to treat diabetes. Unlike humans, the zebrafish can efficiently regenerate beta cells, notably from ductal pancreatic progenitors. To gain insight into the molecular pathways involved in this process, we established the transcriptomic profile of the ductal cells after beta cell ablation in the adult zebrafish. These data highlighted the protein phosphatase calcineurin as a new potential modulator of beta cell regeneration. We showed that calcineurin overexpression abolished the regenerative response, leading to glycemia dysregulation. On the opposite, calcineurin inhibition increased ductal cell proliferation and subsequent beta cell regeneration. Interestingly, the enhanced proliferation of the progenitors was paradoxically coupled with their exhaustion. This suggests that the proliferating progenitors are next entering in differentiation. Calcineurin appears as a guardian which prevents an excessive progenitor proliferation to preserve the pool of progenitors. Altogether, our findings reveal calcineurin as a key player in the balance between proliferation and differentiation to enable a proper beta cell regeneration.
Introduction
Blood glucose homeostasis is tightly controlled by pancreatic endocrine cells. Insulin-producing beta cells work in close association with alpha cells, which secrete glucagon, and delta cells secreting somatostatin, to maintain normal glycemia. The insulin plays a critical role in this process as it is the only hormone able to lower the glycemia. Beta cell loss is a hallmark of type 1 and of late stages of type 2 diabetes, leading to chronic hyperglycemia. Beta cell destruction is largely irreversible in human and in mammals, making the disease incurable nowadays. Nevertheless, studies in diabetic mice models uncovered promising evidences of slight recovery of beta cells via regeneration. For example, new beta cells can arise from the replication of remaining beta cells [1]. Different models of pancreas injuries revealed the plasticity of mammalian pancreatic cells. Actually, differentiated endocrine cells such as alpha cells[2] and delta cells[3] can reprogram and convert into insulin-producing cells, a process that is age dependent. Another possible source of beta cells could be de novo formation from pancreatic progenitors residing in the ductal compartment of the adult pancreas [4]. Lineage tracing experiments could not clearly highlight new beta cells arising from the ductal cells in the adult [4]–[6]. However, expression of the pro-endocrine marker Neurog3 was detected in the ducts in different mouse models of pancreas regeneration [4], [7], [8]. In addition, a rare population of ductal cells expressing Neurog3 has been reported to contribute to beta cell neogenesis during diabetes [9]. A recent study of single cell RNA sequencing reveal a sub-population of human ductal cells which are able to give rise to all the pancreatic cell types, including beta cells, following implantation in mice [10]. Altogether, these findings suggest that mammalian pancreatic ducts possess the intrinsic capacity to (re)generate beta cells even though this process is poorly efficient and slow, especially in adults. In contrast to mammals, zebrafish possess remarkable capacity of regeneration, independently of its age [11]–[16]. This model can therefore be exploited to identify and characterize regenerative mechanisms and ultimately induce regeneration in mammals. Based on regenerative mechanisms identified in zebrafish, several studies succeed to improve regeneration in mammals, underlying the possibility of translation from zebrafish to mammals ([17]–[21] and [22], for review).
In zebrafish, the nitroreductase (NTR)/nitroaromatic prodrug system is widely used. In this technique, the combination of cell type-specific NTR expression and nitroaromatic prodrug exposure allow for controlled and targeted cell ablation [23], [24]. When NTR is expressed under the control of the insulin (ins) promoter (Tg(ins:NTR-mCherry) [25]), beta cell destruction is complete within 3 days following the treatment in adult fish, which correlate with a peak of hyperglycemia [26], [27]. The regeneration of beta cells upon ablation is spontaneous and fast and the glycemia is normalized within two weeks [13], [29]. Similar to mice, new beta cells can arise through proliferation of surviving beta cells [28] as well as through the contribution of alpha cells [29], [30] and delta cells[31], [32], underscoring the overall conservation of these processes from zebrafish to mammals. Nevertheless, unlike mammals, the presence of pancreatic progenitors in the ducts is well established in both larval [33] and adult zebrafish [26], [27]. Lineage tracing experiments pointed out that ductal cells and centroacinar cells (CACs) give rise to new beta cells [26], [33]. In adults, duct-derived beta cells start to be detected between 7 and 10 days following beta cell ablation [26], [27].
Notch signaling is a key player regulating the differentiation of duct-associated progenitors into endocrine cells. Larval duct cells as well as adult CACs display strong Notch activity [26], [34]. This signaling pathway has a central role in beta cell genesis during both development [35] and regeneration [33] by repressing endocrine differentiation. In zebrafish, different levels of Notch activity determine the behavior of the pancreatic progenitors. While a high level of Notch activity maintains cells in quiescence, a moderate level induces the entry in the cell cycle and proliferation whereas a low level drives endocrine differentiation of the progenitor cells [35]. A steep decrease of Notch activity pushes the progenitors to differentiate prematurely, bypassing the amplification step and leading to their depletion [35]. Repression of the Notch signaling by mTor, activated by glucose and nutrients, hence promotes beta cell formation and regeneration from ductal progenitors [33]. While Notch and mTor signaling are crucial for this process, there is still a need to establish a global view of the molecular mechanisms regulating beta cell regeneration.
To identify early events regulating ductal-derived beta cell regeneration, we determined the transcriptomic signature of ductal cells from adult zebrafish following beta cell destruction. Our data highlighted an upregulation of the Calcineurin (CaN) pathway. To elucidate CaN function in beta cell regeneration, we both repressed and activated CaN pathway. We showed that CaN regulates beta cell neogenesis in the ducts during regeneration, by acting on progenitor proliferation. Together, our findings underline that CaN fine tunes the balance between progenitor proliferation and beta cell differentiation to guarantee proper regeneration.
Results
Transcriptomic profiling of ductal cells after beta cell destruction highlights regulation of calcineurin pathway
To gain a better understanding of the molecular mechanisms underlying the regeneration of beta cells from the ducts, we determined the transcriptional landscape of ductal cells by RNA-sequencing after beta cell ablation in the adult zebrafish. To selectively ablate the beta cells, we used the Tg(ins:NTR-mCherry) transgenic fish. The ductal cells were labelled thanks to the Tg(nkx6.1:GFP) reporter line [27] in which GFP marks the ductal tree and associated multipotent pancreatic progenitors [27]. More precisely, 3 to 4 fishes were treated with the pro-drug MTZ at 10mM overnight, to induce ablation of beta cells or with DMSO for the non-ablated controls. Ablation was confirmed by blood glucose measurement before collection of the pancreas. To capture the early events triggered by the destruction of beta cells, we generated the transcriptome of the ducts 3 days post ablation treatment (dpt), i.e. before beta cell neogenesis (Figure 1A supplemental). Differential gene expression analysis revealed that 1866 genes are up-regulated and 1515 genes down-regulated in the ductal cell of fish treated with MTZ compared to control (pAdj < 0.05). According to Gene Ontology analysis, the most enriched pathways among the up-regulated genes were DNA replication and cell cycle (Figure 1A). This further corroborates our previous findings and those of others, regarding the activation of duct-associated progenitors’ proliferation in response to beta cell ablation [26], [27]. As expected, the Notch pathway was enriched in the down-regulated genes [33], [35] (Figure 1B). On a contrasting note, in a context marked by a robust proliferative response, we found it intriguing to observe an enrichment in the cellular senescence signature (Figure 1A). Subsequently, we investigated deeper into the genes associated with this specific signature. We found among them several components of the calcineurin signaling pathway such as nfatc3b, ppp3ccb (the catalytic subunit of Calcineurin), itpr2 and calm3b (Figure 1C). In addition to these genes related to the cellular senescence signature, our transcriptomic studies revealed the modulation of other genes from the CaN canonical pathway (Figure 1D), underlying its potential role in beta cell regeneration. Calcineurin (CaN) is a highly conserved calcium/calmodulin dependent Ser/Thr phosphatase, involved in numerous biological process including fin regeneration and beta cell function [36]–[39]. This prompted us to investigate the role of CaN in beta cell regeneration.
Previous RNAseq data performed in our laboratory indicate that CaN (ppp3cca/b) and NFATc3 (nfatc3a/b) are mainly express in endocrine cells [40] (Figure 1B supplemental), which is in accordance with the role of CaN/NFAT signalling in beta cells [41]. CaN genes (ppp3cca/b) as well as nfatc3b, are express at lower levels in the ducts at basal state but their expression is induced in response to beta cell destruction (Figure 1C supplemental).
Calcineurin activity regulates the ductal regenerative response
To evaluate the role of CaN in beta cell regeneration, more specifically derived from ductal progenitors, we have chosen to use young larvae, where regenerated beta cells in the pancreatic tail arise exclusively from the ducts [33]. In response to beta cells ablation, the intrapancreatic ducts undergo a ductal regenerative response whereby differentiation toward the endocrine fate is increased [33]. We first determined the rate of beta cell neogenesis from the ducts in response to a single acute ablation of beta cells as we performed in adults. We treated Tg(ins:NTR-P2A-mCherry); Tg(nkx6.1:GFP) larvae with nifurpirinol (NFP) from 3 to 4 dpf and mCherry+ beta cells were quantified in the GFP+ ducts in the pancreatic tail at several time points: 4, 7, 10 and 14 dpt (Figure 1E). Duct-associated beta cells started to be detected in non-ablated larvae between 7 and 10 dpt (Figure 1F) and the number of beta cells slowly increased until 14 dpt (Figure 1F, 1G). In ablated larvae, the increase became more pronounced from 10 dpt onwards (Figure 1F, 1G), indicating faster endocrine differentiation. This experiment establishes that the ductal regenerative response is detectable between 10 and 14 days after the beta cell ablation, performed at 3 dpf. We next wanted to determine if ductal cell proliferation is activated in response to beta cell destruction in larvae as in adult fish. We exposed Tg(ins:NTR-P2A-mCherry); Tg(nkx6.1:GFP) larvae to EdU the second day following ablation (Figure 1H). In the ablated larvae, the proportion of GFP+ ductal cells EdU+ (in S-phase) was higher compared to non-ablated larvae (Figure 1I, 1J). This result shows that acute beta cell ablation in larvae rapidly activates ductal cell proliferation, as previously reported in adult zebrafish.
As our transcriptomic data from adult zebrafish revealed modulation of the CaN pathway at 3 dpt (Figure 1D), we treated Tg(ins:NTR-P2A-mCherry); Tg(nkx6.1:GFP) larvae from 1 to 3 dpt after beta cell ablation, with a CaN inhibitor, the Cyclosporin A (CsA) [39] (Figure 2A). The number of newly formed beta cells in the tail was monitored from 4 to 14 dpt. CsA enhanced beta cell formation at 10 dpt (Figure 2B-D). However, this effect appears to be transient since no discernible difference was observed between the control and CsA-treated larvae in regeneration at the latest time point (14dpt), suggesting an acceleration of the regenerative response (Figure 2B, Figure 2A supplemental). Interestingly, CsA did not affect beta cell differentiation in non-ablated larvae, indicating that CsA only acts in a regenerative context (Figure 2B-D). Of note, CsA increased as well the number of regenerated beta cells in the principal islet (Figure 2B, 2C supplemental). We and others, previously showed that the other major source of beta cell regeneration, besides the ducts, are the bi-hormonal sst1.1+/ins+ cells [31], [32], [42]. However, CsA did not affect bi-hormonal cell formation (Figure 2D supplemental), suggesting that the additional cells in the principal islet could also originate from the ducts.
We next tested the effect of CsA on endocrine progenitors in a regenerative context. We induced regeneration in Tg(neurod1:GFP) larvae where the GFP is expressed in both endocrine progenitors and mature endocrine cells. We first assessed generation of GFP cells at different time points (Figure 2E supplemental) and showed that CsA induced an increase of neurod1+ cells from 4 dpt. The increase was still detectable at least until 10dpt (Figure 2E, Figure 2F supplemental). To determine if these additional cells result from their own proliferation, we performed a pulse of EdU just before analysis (Figure 2E supplemental). We observed that CsA did not affect the neurod1+ cell proliferation rate, which is very low at these stages (Figure 2F). As a consequence, the effect of CsA cannot be explained by endocrine cell proliferation but rather by neogenesis from progenitors. As CsA affects pro-endocrine cells formation, we next wondered if the increased cell formation induced by CsA is specific to beta cells. Treatment with CsA was performed as previously and delta1.1 and alpha cells were detected by immunofluorescence. Interestingly, CsA did not affect alpha nor delta1.1 cells neogenesis in response to beta cell ablation (Figure 2G-H supplemental). Overall, these experiments showed that CsA affects specifically the beta cells and their endocrine progenitors.
CaN over-activation abolishes the regenerative response
We then wondered if an opposite regulation of CaN i.e. its activation impacts as well the regenerative response. To that end, we generated a transgenic line Tg(hsp70:GFP-P2A-ppp3ccCA) that allows ubiquitous expression of a constitutively active form of CaNCA (ppp3ccCA) upon heat shocks. Beta cell ablation was triggered in Tg(hsp70:GFP-P2A-ppp3ccCA); Tg(ins:NTR-P2A-mCherry); Tg(nkx6.1:GFP) larvae from 3 to 4 dpf and CaNCA expression was induced by four successive heat-shocks from 1 to 3 dpt (Figure 3A). The overexpression of CaNCA after ablation impaired the regenerative response at 14 dpt (Figure 3B-C). Similar results were obtained with Tg(UAS:GFP-P2A-ppp3ccCA); Tg(cftr:gal4)[45]; Tg(ins:NTR-P2A-mCherry) larvae in which CaNCA is continuously and specifically overexpressed in the ducts within the pancreas (Figure 3D-E). Importantly, the structure of the ducts was similar in CaNCA overexpressing larvae compared to Tg(nkx6.1:GFP) controls (Figure 3D), suggesting that the suppression of the regenerative response in CaNCA-overexpressing larvae was not due to morphogenetic defects during ductal growth. This result shows that CaN acts directly in the ducts to decrease beta cell regeneration while it is not necessary for normal beta cell differentiation.
CaN regulates beta cell differentiation induced by Notch inhibition in absence of regeneration
Our transcriptomic data showed that the Notch pathway is downregulated in ductal cells during beta cell regeneration (Figure 1). As the level of Notch activity determines the behavior of ductal cells [33] from quiescence to proliferation and subsequently to beta cell differentiation, we tested whether calcineurin acts together with the Notch pathway on a common pool of ductal progenitors. To inhibit the Notch pathway, we treated larvae with several concentrations of the gamma-secretase inhibitor LY411575 from 3 to 4dpf in absence of regeneration. The activity of CaN was inhibited by CsA during the same timeframe (Figure 4A). As previously, we used reporter lines for beta and ductal cells Tg(ins:NTR-P2A-mCherry); Tg(nkx6.1:GFP) and the number of secondary beta cells was analyzed at 6dpf (Figure 4A). As expected, the number of beta cells progressively rose as the concentration of the Notch inhibitor increased (Figure 4B). Combined treatment with CsA fostered the differentiation of beta cells between 1 and 10 µM LY411575 but did not result in further increase at 15 µM LY411575 (Figure 4B), suggesting that CaN is important within a permissive window of Notch activity. Since we overserved the highest synergistic effect at 5µM of LY411575, we used this concentration for the following experiments (Figure 4C-D). It is worth noting that combined treatment of LY411575 (5uM) and another CaN inhibitor, FK506, resulted in the same synergistic increase of beta cell differentiation (Figure 4A-B supplemental), confirming that the effect is well due to CaN inhibition. The combined effect of Notch and CaN inhibition is transient as it is not observed at 7dpf anymore (Figure 4E). Therefore, as observed in regenerative conditions (Figure 2B), CaN inhibition accelerates beta cell neogenesis induced by Notch repression.
To determine to which extent CaN pathway can modulate Notch induced beta cell neogenesis, we activated CaNCA overexpression in Tg(hsp70:GFP-P2A-ppp3ccCA); Tg(ins:NTR-P2A-mCherry) larvae by an heat-shock at 3 dpf and treated them with LY411575 (Figure 4C supplemental). CaNCA overexpression resulted in a lowered beta cell formation induced by Notch inhibition (Figure 4D supplemental), revealing that CaN activation counterbalanced the effects of Notch inhibition. Using our previous settings of Notch and CaN inhibition, we next wondered if the canonical pathway downstream of CaN was involved in the enhancement of beta cell differentiation. To activate NFAT, a well-known target of CaN, we used CHIR99021 allowing a stabilization of the active form of NFAT (Figure 1D). We found that CHIR99021 rescued the effect of CsA (Figure 4E supplemental), suggesting that CaN inhibition increases beta cell neogenesis at least partially by the regulation of NFAT. Overall, these results reveal that CaN impacts beta cell formation in pro-endocrinogenic context, such as induced by a low level of Notch activity. Moreover, it suggests that both CaN and Notch pathways act on a common pool of ductal progenitors to govern beta cell neogenesis.
CaN controls the proliferation of duct-associated progenitors induced by Notch inhibition
Given that we observed the most significant increase in beta cell formation with CsA when Notch activity was mildly repressed (Figure 4B-D), and since mild Notch activity has been shown to promote progenitor amplification [35], it suggests that CaN acts at this level. To explore this possibility, we exposed briefly Tg(nkx6.1:GFP) larvae to EdU after mild Notch (LY411575 5µM) and CaN inhibition (Figure 5A) and analyzed at 4dpf and 6dpf. As expected, Notch inhibition increased the proportion of proliferating EdU+ GFP+ ductal cells at 4dpf (Figure 5B-C) while the number of GFP+ ductal cells remained constant (Figure 5A supplemental). Furthermore, the amount of ductal progenitors decreased 2 days later (at 6dpf) (Figure 5D), which is concomitant with the increase of beta cell differentiation (Figure 4C-D). Interestingly, the combined inhibition with CsA further increased these proportions, while CaN inhibition alone had no effect (Figure 5B-D). Of note, we detected beta cells EdU+ at 6dpf (Figure 5B supplemental), underlying that these cells originate from the proliferation of ductal progenitors.
Incidentally, at 4dpf, while the proliferation is increased (Figure 5C), the number of ductal cells remained the same in all conditions (Figure 5A supplemental), suggesting that ductal cells have not yet left the cell cycle to differentiate. In comparison, after stronger Notch inhibition (15µM), the ductal cells are already depleted at 4dpf (Figure 5C supplemental), as they directly differentiate without entering the cell cycle [35]. In these conditions, CsA could therefore not enhance ductal progenitor proliferation and thus beta cell formation (Figure 4B). These results show that CaN and Notch pathways act together on the proliferation of the ductal progenitors to prevent their exhaustion.
CaN prevents exhaustion of Notch responsive progenitors during beta cell regeneration
Taken together, our results indicate that CaN plays a role in the proliferation of ductal progenitors in contexts that are permissive for beta cell differentiation. To demonstrate that CaN acts on ductal progenitor proliferation in a similar manner to Notch inhibition but during regeneration, we exposed Tg(ins:NTR-P2A-mCherry); Tg(nkx6.1:GFP) larvae after ablation and CsA treatment (Figure 5E). CaN inhibition enhanced the proliferation of ductal cells in ablated larvae (Figure 5F-G). To next determine if CaN acts on the Notch-responsive progenitors in beta cell regeneration, we then used Tg(tp1:VenusPest) Notch reporter line. At larval stages the vast majority of ductal cells are Notch responsive and the reporter line marks all the progenitors within the ductal tree [34]. We treated Tg(ins:NTR-P2A-mCherry); Tg(tp1:VenusPest) as described above (Figure 5E). In ablated-larvae, CsA increased tp1+ ductal cell proliferation (Figure 5H-I). Moreover, CsA induced a reduction of tp1+ ductal cells in ablated larvae (Figure 5 H-J), suggesting an exhaustion of the Notch responsive progenitors, in accordance with premature beta cell differentiation we observed (Figure 2B-4D). Lastly, CsA does not affect tp1+ cells in non-ablated larvae showing that CaN inhibition did not directly affect Notch signaling (Figure 5J). Those results suggest that CaN fine tunes the balance between proliferation of the progenitors and their differentiation to prevent their exhaustion during beta cell regeneration.
CaN regulation is functionally relevant in adult zebrafish
To further expand upon our findings and investigate their relevance in a non-developmental context, we next ought to determine whether CaN function is maintained in older zebrafish. We used 2 months old Tg(ins:NTR-P2A-mCherry); Tg(nkx6.1:GFP) juveniles fish to perform beta cell ablation followed by CsA treatments. We analyzed the number of small islets (up to 5 cells) at 7 and 10dpt. At 7dpt, CsA increased the number of small islets in ablated juveniles (Figure 6A-B) showing that CaN inhibition enhances beta cell regeneration in juvenile zebrafish, as in larvae. It is noteworthy that, as in larvae, we highlighted an acceleration of beta cell regeneration. The increase number of small islets is indeed transient as it not observe anymore at 10dpt (Figure 6C).
Next, we determined the functional impact of CaN overexpression or inhibition by assessing the glycemia at 7, 10 and 14 after beta cell ablation. Overexpression of CaNCA using either Tg(hsp70:GFP-P2A-ppp3ccCA) or Tg(cftr:gal4); Tg(UAS:GFP-P2A-ppp3ccCA), led to an increased glycemia at both 7 and 10dpt (Figure 6D-E), before recovery at 14 dpt (Figure 6A supplemental). This indicates that the overexpression of CaN delayed glycemia recovery induced by beta cell regeneration. However, CaN inhibition did not seem to further improve the glycemia (Figure 6D-E) probably because the glycemia was already low at 7dpt (77 mg/dL on average) compared to non-ablated control (50 mg/dl on average) (Figure 6D-E). Altogether, these results show that in adult zebrafish also, CaN regulation is necessary to enable beta cell regeneration and for proper recovery of the glycemia after beta cell loss.
Discussion
Previous drug and genetic screening using zebrafish larvae enabled the identification of several regulators of beta cell regeneration from different pancreatic cellular sources. For example, adenosine has been shown to stimulate beta cell replication [28], igfbp1a [43] and TGFb suppression [30] promote alpha-to-beta cell transdifferentiation. As for cdk5 inhibition and folinic acid/Folr1, they promote beta cell regeneration from the pancreatic ducts [44], [45]. Here, to identify novel regulators of beta cell regeneration specifically from pancreatic ducts, we carried out a transcriptomic profiling of duct cells following beta cell ablation in the adult zebrafish. Transcriptomic analyses show that the regulated genes encompass most of the genes and pathways identified in previous studies (igfbp1, mTor, Notch, etc.), underlying the importance of those actors in beta cell regeneration. Our data reveal also that DNA replication is the most enriched signature attesting that duct cells undergo a potent proliferative response after the destruction of beta cells.
Besides these expected signatures, our transcriptomic data uncover the unanticipated upregulation of numerous genes implicated in DNA repair and cell cycle arrest. These signatures might indicate that highly proliferating ductal cells activate counteracting mechanisms. Among the genes regulated in those signatures, we focused on CaN and determined its role in beta cell regeneration. In an experimental setting in the young larvae revealing regeneration from the ducts [33], pharmacological inhibition of CaN increases the proliferation of duct cells induced by beta cell ablation, resulting in an acceleration of beta cell regeneration in the ducts. Consistently, we also used a genetic approach, and showed that transgene-mediated CaN overactivation abolishes the regenerative response. Importantly, the inhibition of regeneration is observed when CaN is overexpressed either ubiquitously or selectively in cftr-expressing ductal cells indicating that the role of CaN in beta cell regeneration is intrinsic to the ducts. Moreover, we showed that CaN acts on the same pool of ductal progenitors than Notch pathway and together control their proliferation and differentiation to beta cells. Altogether, these experiments confirm that the increased of beta cells induced by CaN originate from the ducts in the pancreatic tail. Nonetheless, while these experiments provide strong evidences, performing lineage tracing would further reinforce these data. We also suggest that CaN could improve regeneration in the principal islet, however as the molecular mechanisms of regeneration from the extra pancreatic ducts are not Notch dependant, it would be interesting to investigate the mechanisms under CaN inhibition.
Based on functional assays in larvae, we not only confirm the activation of the proliferation of ductal cells soon after beta cell ablation, but also that the rate of progenitor proliferation is carefully controlled by CaN in order to achieve proper and timely regeneration of beta cells. Our data are consistent with earlier studies reporting a role of CaN in proliferation dynamics during fin regeneration. In the regenerating fin, low CaN activity is found in the proximal region of the blastema characterized by a high rate of proliferation and regeneration and its activity increases distally where lower proliferation is observed [36], [38], [39]. It was suggested that CaN control blastemal cell progeny divisions [36]. In human, the importance of CaN in proliferation is also highlighted in organ transplanted patients. When patients are treated with Cyclosporin A (i.e. the CaN inhibitor we used in this study) as immunosuppressive drug they indeed present an increased risk of skin cancer, notably due to keratinocyte senescence inhibition [46].
It has been shown that Notch inhibitory treatments switch progenitors from proliferative self-renewing to premature differentiation, leading to progenitor depletion [34], [35]. Our study reveals that this phenomenon is further exacerbated by CaN inhibition. Importantly, during normal larval development in absence of Notch inhibitory treatment, CaN does not affect basal ductal proliferation nor beta cell differentiation. Hence, Notch signalling has to be repressed to detect the effect of CaN on the progenitors, suggesting that CaN acts downstream of Notch pathway. In differentiating keratinocytes, CaN cooperates with Notch signalling to regulate p21/cdkn1a (which is upregulated in the ducts at 3 dpt), cell cycle withdrawal and differentiation [47]. These studies show that CaN acts in association with Notch signalling on progenitors proliferation and on their differentiation.
Based on our data, we build the model depicted in Figure 7A. Our study suggests that CaN acts in competent progenitor cells and that this competence is determined by Notch signalling. When Notch is repressed to a mild level, the progenitor enter into the cell cycle and acquire a pro-endocrinogenic competence [35]. CaN acts on these progenitors to tone down an excessive proliferation and avoid the exhaustion of these progenitors. CaN is therefore a guardian of the progenitor population. CaN inhibition both increases progenitor proliferation and induces their depletion, suggesting a switch to a symmetric division resulting in two daughter cells entering in endocrine differentiation.
More precisely, a previous study in mice uncover the existence of three division modes of the pancreatic progenitors during embryonic development, i.e. symmetric self-renewing resulting in two progenitors cells; asymmetric resulting in a progenitor and a endocrine cell and symmetric differentiative resulting in two differentiated cells [48]. The authors actually show that the type of division is defined by the timing of induction of endocrine program by NEUROG3 [48]. Interestingly, NEUROG3 seems to be the link between proliferation and differentiation, and its expression is regulated by Notch signalling [49]. In zebrafish, endocrine differentiation is not induced by Neurog3 but by Ascl1b and Neurod1 [50]. Concerning that subject, CaN inhibition accelerates the formation of neurod1+ cells. Hence CaN could possibly act via the determination of the type of division i.e. symmetric vs asymmetric. This model is supported by previous observation in others systems. In stem cells and neuronal and hematopoietic progenitors, premature differentiation results from a switch in the mode of cellular division, from symmetric amplifying division to asymmetric differentiating division [51], [52]. Notch determines the choice between both types of divisions [53], [54].
Calcineurin is known to be implicated in cellular senescence [46]. Usually thought as negative regulators of development and cellular growth, DNA repair [55] and cellular senescence [56] appear to be required in both developmental and regenerative processes. Our transcriptomic data suggest that these mechanisms are required for beta cell regeneration. Therefore, it would be interesting to determine the contribution of these cellular processes in the ductal progenitors and determine if CaN acts via cellular senescence in this case.
Overall, this study brings new insights on beta cell regeneration and highlights the ductal progenitor cell cycle as a cornerstone in the process. Some studies report an increase of proliferation of some ductal cell population in diabetic patients [10], [57], implying a regenerative response. However, these ductal cells cannot efficiently reform the beta cell mass, suggesting a dormant mechanism of regeneration. As such, the balance between proliferation and induction of endocrine differentiation could be a key to improve beta cell neogenesis. However, as CaN is also important for beta cell function, this approach would require to be transient to induce neogenesis. Therefore, it should be combined with methods to induce beta cell proliferation to ultimately reconstitute the beta cell mass. Overall, this study brings a better understanding on the regulation of the balance between ductal progenitors proliferation and endocrine differentiation. These results should provide new hints to help improve regenerative competences in mammals.
Material and Methods
Key resources table
Zebrafish husbandry and generation of the Tg(hsp70:eGFP-P2A-ppp3ccaCA)ulg068 and Tg(UAS:eGFP-P2A-ppp2ccaCA)ulg069 zebrafish lines
Tg BAC(nkx6.1:eGFP)ulg004 [58] ; Tg(ins:NTR-P2A-mCherry)ulg034 [59] ; Tg(cftr:gal4) and Tg(tp1:VenusPest) were used. Zebrafish were raised in standard conditions at 28°C. All experiments were carried out in compliance with the European Union and Belgian law and with the approval of the ULiège Ethical Committee for experiments with laboratory animals (approval number: 2075).
The hsp70:GFP-P2A-ppp3ccaCA transgene has been generated by cloning a PCR fragment containing the Gateway vector pCR8/GW/TOPO. Firstly, we amplified the full length of ppp3ccaCA with primers IM369/IM380 and amplified GFP-P2A with overlapping regions with IM371/O226. The overlapping PCR used the primers O226/IM380. Then to obtain a truncated ppp3ccaCA lacking the calmodulin biding and the autoinhibitory domain, resulting in a constantly active form of calcineurin, we amplified the last fragments with IM370/O226 and cloned into PCR8 vector. The promoter was assembled by LR recombination with pE5-hsp70 into pDestTol2p2A from the Tol2kit [60]. Tg (hsp70:GFP-P2A-ppp3ccaCA) fish have been generated using the Tol2 mediated transgenesis [61]. The Tg(UAS:GFP-P2A-ppp3ccacA) has been generated by ligation (KLD kit, NEB) of PCR fragments GFP-P2A-ppp3ccacA (IM459/IM460) with the UAS sequences (IM457/IM458) in plasmid from (Distel 2009) and then inserted into pDestTol2p2A from the Tol2kit. Final constructions has been injected with transposase into wild type (WT) AB embryos.
Beta-cell ablation
Adults fish for RNA-sequencing experiment were treated with freshly prepared metronidazole (MTZ) (Sigma M1547) at 10mM with 0.2% DMSO in fish water. Control treatments consisted of fish water containing 0.2% DMSO. Fish were treated for 18 hours in the dark. Nifurpirinol (NFP) (32439, Sigma-Aldrich) stock solution was dissolved at 2.5 mM in DMSO. b-cell ablation in Tg(nkx6.1:eGFP); Tg(ins:NTR-P2A-mCherry) larvae was induced by treatment with 2.5 µM NFP in E3. Control treatments consisted of E3 containing 0.2% DMSO. Larvae were treated for 18 hours in the dark.
Drug treatments
Cyclosporine A (Selleckchem, S2286), CHIR99021 and LY411575 (Sigma-Aldrich, SML0506) stock solution were dissolved at 10mM in DMSO. Larvae treatment were respectively performed at 0.1 µM and 5µM in E3. Control treatments consisted of E3 containing the same amount of DMSO than drug treatment. Larvae were treated for 18 hours in the dark.
5-ethynyl-2′-deoxyuridine (EdU) incorporation assay
Zebrafish larvae were incubated in 4 mM EdU dissolved in E3 water for 8 hours, they were then directly euthanised in tricaine and fixed in 4% PFA. EdU was detected according to the protocol of Click-iT™ EdU Cell Proliferation Kit for Imaging, Alexa Fluor™ 647 (ThermoFisher C10340) after whole mount immunodetection.
Heat Shock
Successive heat shocks of 30 minutes and 12 hours apart were performed at 39°C for larvae and 37°C for juveniles and adults zebrafish.
Whole mount immunodetection
Larvae were euthanized in tricaine and fixed in 4% PFA at 4 °C for IHC. The digestive tract of juveniles was dissected prior immunodetection and kept in methanol for at least 18 hours. After depigmentation with 3% H2O2/1% KOH, larvae were permeabilised 30 min in PBS/ Triton X-100 and incubated for two hours in blocking buffer (4% goat serum/1% BSA/PBS/0.1% Triton X-100). Primary and secondary antibodies were incubated at 4 °C overnight.
Primary antibodies: Living Colors Polyclonal anti-mCherry/dsRed (rabbit, 1:500, Clontech 632496), anti-GFP (chicken, 1:1000),
Secondary antibodies: Alexa Fluor-488, −568, −633 (goat, 1:750, Molecular Probes).
Flow cytometry and FACS
The whole pancreas from 3-4 fish of Tg(nkx6.1:eGFP); Tg(ins:NTR-P2A-mCherry) adult fish (6–10 months old, males and females) were dissected, collected and washed in HBSS without Ca2+/Mg2+. Live cell dissociation was performed in Tryple Select 1x solution (GIBCO) supplemented with 100 U/mL collagenase IV (Life Technologies 17104-019) and 40 µg/mL proteinase K (Invitrogen, 25530031) for 10 min at 28 °C.
The GFP+ cells were selected on FACS Aria III and sorted under purity mode and after exclusion of the doublets. The purity of the sorted cells was confirmed by epifluorescence microscopy (∼95 %). Cells (about 1000-5000/fish depending on the cell type) were immediately lysed with 0.5% Triton X-100 containing 2U/µl RNAse inhibitor and stored at –80 °C.
mRNA sequencing of FACSed cells and bioinformatic analyses
cDNAs were prepared from lysed cells according to SMART-Seq2.0 (Picelli et al., 2014) for low input RNA sequencing and libraries were prepared with Nextera® DNA Library kit (Illumina). Independent biological replicates of each cell type sequenced using Illumina NextSeq500 and obtained ∼20 million 100 bp paired-end reads. Reads were mapped and aligned to the zebrafish genome GRCz11 from Ensembl gene annotation version using STAR version 2.6.1 (Dobin et al., 2013). Gene expression levels were calculated with featureCounts (http://bioinf.wehi.edu.au/featureCounts/) and differential expression determined with DESeq2 (Love, Huber, & Anders, 2014). Expression values are given as normalized read counts. Poorly expressed genes with mean normalized expression counts <10 were excluded from the subsequent analyses. DESeq2 uses Wald test for significance with posterior adjustment of P values (Padj) using Benjamini and Hochberg multiple testing. The differentially expressed (DE) genes identified with a Padj cutoff of 0.05 were submitted for GO analysis using WebGestalt tool (Liao, Wang, Jaehnig, Shi, &Zhang, 2019).
Confocal microscopy and image analysis
Images were acquired using Leica SP5 confocal microscope. We used ImageJ to count the cells and Imaris to do the pictures.
Glycemia measurement
Glycemia measurement were performed as described in [59].
Data availability
The sequences that support the findings are of this study have been deposit in Geo with the accessions codes GSE212124, https://www.ncbi.nlm.nih.gov/geo/info/linking.html. The authors declare that all other data supporting the findings of this study are available within the paper and its supplementary information files.
Authors contribution
L.M. conducted experiments, acquired and analysed data, analysed transcriptomic data, wrote the manuscript. D.B. conducted RNA-seq experiment and revised the manuscript A.L. implemented bioinformatic programs and analysed transcriptomic data. C.R., C.G. and C.D. conducted experiments.
L.F. revised the manuscript. B.P. provided resources and advised on research studies. M.L.V. provided resources, advised on research studies and revised the manuscript I.M. supervised the whole work, acquired funding, designed the research studies, verified data and assisted in writing the manuscript.
Supporting information
Acknowledgements
The authors thank the EOS (Excellence of Sciences) program from FNRS and more especially Dr. Emmanuel Dejardin for support. We also thank the GIGA technology platforms, GIGA-Genomics and GIGA-Imaging. The authors also thanks Jérémie Zappia for critically reading the manuscript, Jordane Bourdouxhe and Marie Alice Dupont for their help with the constructions.
Duality of interest
No potential conflicts of interest.
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