Y-to-PDA direct reprogramming is blocked in unc-3 mutants

To dissect the mechanisms underlying Y cell conversion, we carried out a mutagenesis screen for mutants unable to successfully reprogram Y into PDA. Our genetic screen provided mutants that fall into different classes based on the morphology and numbers of cells in the rectal area. We focused on one allele, fp8, in which the Y-to-PDA reprogramming may have been initiated, as judged by the number of rectal cells, but lacked a PDA neuron and could thus affect intermediate steps of Y-to-PDA reprogramming. SNP mapping, sequencing and non-complementation between a null allele of the unc-3 gene and our fp8 allele revealed that a conserved residue in the DNA-binding domain of UNC-3 was mutated in fp8, causing the Y-to-PDA reprogramming defect (Fig. 1C,D). UNC-3 is the sole C. elegans member of the conserved COE (Collier/Olf-1/EBF) transcription factor family, which is involved in cell fate determination, including neuronal differentiation (Dubois and Vincent, 2001). Analysis of other unc-3 alleles confirmed that a Y-to-PDA reprogramming defect is observed when the activity of this gene is lowered (Fig. 1E). We found that all unc-3 alleles that resulted in the destruction of the zinc-finger coordination motif of the DNA-binding domain (n3413, n3435 and e95), or in the disruption of the IPT domain (oy85, e151), led to the most penetrant Y-to-PDA defect (Fig. 1E,D; see Materials and methods). By contrast, substitutions (fp8, e121) or late stops (e54) did not appear to strongly alter unc-3 activity during Y-to-PDA transdifferentiation (Fig. 1E; see Materials and methods). We focused on unc-3(e151), the reference allele that has been described as a null allele (Prasad et al., 1998) and which affects Y-to-PDA conversion with high penetrance (Fig. 1D-F).

Y transdifferentiation is initiated normally in unc-3 mutants

How differentiated cells change identity is a fascinating problem in cell biology. There are two potential mechanisms for how this occurs without cell division: (1) concomitant loss and gain of the initial and final cell identities, respectively, with a transient mixed identity stage (Fig. 2A); (2) transition through distinct intermediary cells that lack either of the two identities (Fig. 2A). To determine which mechanism occurs during natural cellular reprogramming in vivo, we examined Y fate in unc-3(e151) animals and sought to determine how the Y-to-PDA process is affected. In unc-3(e151), as in unc-3(fp8) mutants and wild-type (WT) animals, a Y cell is initially born, as assessed by Nomarski optics and expression of an egl-26 transgene (Jarriault et al., 2008) at the L1 stage (Fig. 2B,D). Comparison of the expression of egl-26 and egl-5 transgenes, which are differentially expressed in the rectal cells at different time points of Y-to-PDA reprogramming (Fig. 2D,E), revealed that a Y cell is no longer found in the rectum of unc-3(e151) mutants at later larval stages (L3 and onwards, Fig. 2B-E). These observations suggest that the Y cell develops normally in unc-3(e151) mutants and later moves away from the rectum, as observed when Y conversion is initiated normally in WT animals. However, in unc-3 mutants, this cell never transforms into PDA.

It could be that the Y-to-PDA conversion is blocked mid-process in unc-3 mutants, or that the Y cell migrates to an abnormal position or undergoes cell death. To discount these latter possibilities, we identified a marker [ina-1p::GFP (Baum and Garriga, 1997)] that is expressed in Y and remains expressed during its migration, allowing tracking of the moving cell. Analysis of ina-1p::GFP in WT and unc-3(e151) backgrounds showed that the Y cell correctly migrates to its final position in unc-3 mutants and does not die (Fig. 3A). Nomarski optics also revealed the presence of the abnormal Y cell in unc-3 mutants at its final position (see Fig. 4A). Thus, in unc-3 mutants, the early phase of Y reprogramming (retraction from the rectum and migration) are initiated normally, as in the WT. From now on, we will refer to the cell found at the Y final position in unc-3 mutant L3 larvae as ‘intermediate Y.1’, to distinguish it from the rectal Y found initially in young L1 larvae in both the WT and unc-3 backgrounds.

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Fig. 2

Model for direct reprogramming and initiation of process in unc-3 mutants. (A) Alternative models of cellular reprogramming: (1) the initial (A) and final (B) cell identities overlap during transition; and (2) an intermediate cell state exists that lacks both identities. (B,C) Expression of a Y and P12.pa marker (egl-26 transgene, B) and a Y and U cell marker (egl-5 transgene, C) indicate that a normal Y cell is present in e151 mutants at the L1 larval stage, but is no longer part of the rectum at the L3 larval stage and is replaced by P12.pa. Anterior is to the left and ventral to the bottom. (D,E) Schematics of the egl-5 and egl-26 transgene expression during the L1 to L3 larval stages in WT and unc-3 mutants.

Y-to-PDA transdifferentiation is blocked at an intermediate step in unc-3 mutants

As Y appeared to have initiated its transdifferentiation but failed to become a PDA in unc-3 mutants, we next sought to determine whether Y.1 identity represents a transformation into another cell type or a block in the process. We thus asked whether intermediate Y.1 could have adopted an alternative aberrant identity (Fig. 3B), such as that of a neighbouring cell. Analysis of endodermal, hypodermal or muscle markers in the cell suggested that this was not the case (Fig. 3C). Furthermore, intermediate Y.1 did not adopt the identity of a different neuron type such as a mechanosensory or GABAergic neuron (Fig. 3C). Because cells can transform into their sister cell or their contralateral homologues in C. elegans (Horvitz et al., 1983; Shibata et al., 2010; White et al., 1991), we examined whether the intermediate Y.1 cell had adopted the identity of its sister (the DA7 neuron), of its contralateral homologue (DA9) or of a neuron with a similar morphology (DA8) (Fig. 3D). Examination of markers expressed in these three neuronal types showed that this was not the case (Fig. 3E). Thus, in an unc-3(e151) background, the Y-to-PDA process appears to be blocked at an intermediate step of reprogramming without any obvious aberrant cellular changes. Several additional lines of evidence developed below further support this notion that Y-to-PDA reprogramming is blocked mid-way between the initial Y and the final PDA identity in unc-3 mutants. First, not only Y retraction from the rectum and migration but also loss of expression of the rectal egl-26, egl-5, lin-26 and cki-1 transgenes occur with the same timing in WT and unc-3 mutants. Second, a wild-type unc-3 rescue construct can restore Y-to-PDA reprogramming in unc-3 mutants.

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Fig. 3.

Initiation of Y-to-PDA reprogramming occurs normally in unc-3 animals and does not involve aberrant cellular changes. (A) Presence of ina-1::GFP in Y [expressed as a percentage of total animals scored (n)] as it migrates to its final position. Schematics beneath illustrate Y migration at the different stages examined. (B) Probing of the cellular identity of the intermediate Y.1 cell. (C) Markers of neighbouring cell identities or different neuron subtypes are not expressed in the intermediate Y.1 cell (50 animals scored for each marker). (D) Neuron DA7 is the lineal sister of Y, DA9 is the lineal contralateral homologue of Y, and DA8 is a morphologically related neuron. (E) Intermediate Y.1 did not adopt DA7, DA8 or DA9 identities (50 animals scored for each marker).

Transdifferentiation of Y into PDA is a stepwise process that first involves the erasure of the initial identity

To understand the intermediate stages of direct reprogramming in the absence of cell division or fusion, we further analysed the characteristics of the Y.1 cell in unc-3 mutants. We first examined whether the intermediate Y.1 cell retains any rectal or epithelial characteristics. Morphological analysis using Nomarski optics revealed that it did not exhibit the characteristic ‘fried egg’ epithelial appearance such as is observed in sem-4(n1971) mutants, in which Y-to-PDA transdifferentiation is not initiated and Y remains as a rectal epithelial cell (Jarriault et al., 2008) (Fig. 4A). Furthermore, the intermediate Y.1 cell had lost expression of the egl-26 and egl-5 transgenes (Fig. 2B,C and Fig. 4B) that mark the rectal Y in L1, as well as the expression of a cki-1 transgene, another marker that is expressed in Y but not PDA in the WT (Fig. 4B). Consistent with this, the expression of epithelia-specific markers (che-14, ajm-1, dlg-1 and LIN-26) that are normally expressed in Y was also lost (Fig. 4B). Thus, the intermediate Y.1 cell has lost both the morphological and molecular characteristics of its former rectal epithelial identity.

We next asked whether the intermediate Y.1 cell expresses any neural characteristics. We found three pan-neural markers to be expressed in WT PDA (Fig. 4C, Table 1): unc-119 (Maduro and Pilgrim, 1995), tag-168 (Shioi et al., 2001) and unc-33 (Altun-Gultekin et al., 2001). In unc-3(e151), the penetrance of the ‘No PDA’ phenotype is ~50%. A similar proportion of unc-3(e151) mutants did not express the unc-119 and tag-168 transgenes (Fig. 4C), indicating that the intermediate Y.1 cell does not express these pan-neural markers. The unc-33 transgene, however, the expression of which starts in dividing embryonic neuroblasts (Altun-Gultekin et al., 2001), was expressed in almost all intermediate Y.1 cells in unc-3(e151), suggesting that intermediate Y.1 has begun to acquire early neural properties (Fig. 4C). Accordingly, in rare unc-3(e151) mutants (6%, n=31), the exp-1p::gfp marker could be detected in the Y.1 cell, but no axonal projection from the cell body was observed. This suggests that the intermediate Y.1 cell has not yet adopted neural morphological features. Overall, our evidence indicates that intermediate Y.1 has started to acquire some neural characteristics; however, complete transformation into a neuron is blocked early on.

The identification of this intermediate cellular stage, which is devoid of rectal characteristics and in which neural characteristics have only just begun to appear, supports a model whereby successive distinct cellular steps are undertaken by a cell that directly reprograms in vivo (Fig. 2A, model 2), even in the absence of cell division. To determine whether this is consistent with the WT scenario, we next examined the transient expression of Y and PDA markers in N2 worms during the cellular transition event. The Y cell rectal epithelial markers LIN-26, egl-26, egl-5 and cki-1 were expressed in Y during the L1 larval stage, but were then permanently switched off as Y began its migration (Table 1, Fig. 4D). The PDA markers unc-33 and exp-1 switched on towards the end of Y migration, whereas cog-1 expression was apparent earlier during migration (Table 1, Fig. 4D). Co-staining of LIN-26 and cog-1::GFP, the earliest PDA marker, as well as LIN-26 and unc-33::GFP, revealed that there was never an overlap in expression between the rectal epithelial marker and the neural markers during Y-to-PDA conversion, similar to the sequence of Y identity changes in unc-3(e151) mutants (Table 1). Thus, just after Y retraction from the rectum, the Y cell appeared to transit through a stage that lacked both initial (Y) and final (PDA) identities, and that preceded the appearance of the Y.1 cell with neural character. The erasure of rectal epithelial characteristics prior to the adoption of neural characteristics in WT animals further supports the model whereby successive distinct cellular steps are undertaken by a cell that directly reprograms in vivo (Fig. 2A, model 2). Furthermore, these results also suggest that Y first undergoes dedifferentiation. This transient dedifferentiated intermediary, which we have termed Y.0, appears to quickly initiate redifferentiation into Y.1 as a migrating early neuronal cell.

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Fig. 4.

The intermediate cell in Y-to-PDA reprogramming lacks Y and PDA characteristics. (A) Nomarski (top) and fluorescent (bottom) images of the WT PDA, the Y.1 cell in unc-3(e151) mutants, and the persistent Y in sem-4(n1971) mutants. The location of the PDA, Y.1 and persistent Y cells is boxed and enlarged in the DIC panel insets. Black or white arrowheads indicate rectum. Red arrowhead indicates PDA; no PDA is formed in unc-3 and sem-4 mutants. (B) Y has lost expression of rectal and epithelial markers at the L3 larval stage in both WT and e151 animals (^#60 or *50 animals were scored). (C) Expression of pan-neuronal markers in intermediate Y.1/WT PDA. An early pan-neural marker, unc-33, is expressed in the intermediate Y.1 cell. Error bars represent s.e.m. (*P<0.01, **P<0.001). The total number of animals scored (n) is indicated for each condition. (D) Transient expression of rectal epithelial and neuronal genes during the course of Y-to-PDA reprogramming in WT (see also Table 1).

Dedifferentiation does not lead to an increase in potency in vivo

Dedifferentiation of tissue cells has been achieved in vitro, yielding cells that are highly plastic (Gurdon and Melton, 2008). We sought to assess the plastic potential of the intermediate Y.1 cell, as well as the transient Y.0 cell, in WT and unc-3 mutants. Multipotent cells in C. elegans, such as early blastomeres, can be forced to adopt alternative fates by the ectopic expression of cell fate determinants (Fukushige and Krause, 2005; Quintin et al., 2001; Zhu et al., 1998). To test whether the dedifferentiated intermediate cell could be forced to differentiate into cell types other than PDA, we took advantage of cell fate determinants necessary for specific neural and non-neural lineages that are able to reprogram early C. elegans blastomeres (Fig. 5A). We delivered pulses of hlh-1 [muscle specification (Fukushige and Krause, 2005)], end-1 [intestinal specification (Zhu et al., 1998)], lin-26 [epithelial specification (Quintin et al., 2001)] or unc-30 [GABAergic neuron specification (Jin et al., 1994)] expression through heat shock at different stages of Y-to-PDA transition in order to induce transgene expression before Y began reprogramming and during the intermediate stages of reprogramming (Fig. 5B; see Materials and methods). We validated that the heat shock promoters used to drive the expression of these fate determinant genes drove the expression of GFP in Y under our heat shock conditions, and that mRNA levels of the cell fate determinants used were indeed increased in the transgenic strains after heat shock (see Materials and methods; data not shown). We also delivered a long-term but lower strength heat shock treatment, which we found sufficient to restore Y-to-PDA transformation in unc-3(e151) mutants carrying a hs:unc-3 rescue construct (see Materials and methods). Furthermore, we confirmed that hlh-1, lin-26 and end-1 were capable of reprogramming embryonic blastomeres in an unc-3(e151) background, as in the WT (Fukushige and Krause, 2005; Zhu et al., 1998) (Fig. 5A). Under these conditions, neither the unc-3 nor WT Y.0 cell, nor the intermediate Y.1, could be forced to change into an alternative identity other than PDA (Fig. 5B). This suggests that in both cases (WT and unc-3), the dedifferentiated cell has limited cellular potential and that the intermediate cellular steps of direct reprogramming do not represent reversion to a more plastic state.