Restriction on self-renewing asymmetric division is coupled to terminal asymmetric division in the Drosophila CNS
Authors:
Ivana Gaziova aff001; Michael Gazi aff001; Jordan Mar aff003; Krishna Moorthi Bhat aff001
Authors place of work:
Department of Neuroscience and Cell Biology, University of Texas Medical Branch, Galveston, United States of America
aff001; Texas Biomedical Research Institute, Department of Virology, 8715 W. Military Dr. San Antonio, United States of America
aff002; Department of Molecular Medicine, Morsani College of Medicine, University of South Florida, Tampa, United States of America
aff003
Published in the journal:
Restriction on self-renewing asymmetric division is coupled to terminal asymmetric division in the Drosophila CNS. PLoS Genet 16(9): e32767. doi:10.1371/journal.pgen.1009011
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1009011
Summary
Neuronal precursor cells undergo self-renewing and non-self-renewing asymmetric divisions to generate a large number of neurons of distinct identities. In Drosophila, primary precursor neuroblasts undergo a varying number of self-renewing asymmetric divisions, with one known exception, the MP2 lineage, which undergoes just one terminal asymmetric division similar to the secondary precursor cells. The mechanism and the genes that regulate the transition from self-renewing to non-self-renewing asymmetric division or the number of times a precursor divides is unknown. Here, we show that the T-box transcription factor, Midline (Mid), couples these events. We find that in mid loss of function mutants, MP2 undergoes additional self-renewing asymmetric divisions, the identity of progeny neurons generated dependent upon Numb localization in the parent MP2. MP2 expresses Mid transiently and an over-expression of mid in MP2 can block its division. The mechanism which directs the self-renewing asymmetric division of MP2 in mid involves an upregulation of Cyclin E. Our results indicate that Mid inhibits cyclin E gene expression by binding to a variant Mid-binding site in the cyclin E promoter and represses its expression without entirely abolishing it. Consistent with this, over-expression of cyclin E in MP2 causes its multiple self-renewing asymmetric division. These results reveal a Mid-regulated pathway that restricts the self-renewing asymmetric division potential of cells via inhibiting cyclin E and facilitating their exit from cell cycle.
Keywords:
Gene expression – Cell cycle and cell division – Drosophila melanogaster – Neurons – Statistical data – Precursor cells – Cyclins – Cell division analysis
Introduction
The broad problem of how the division potential of cells is controlled during development is highly significant. The regulation of the division potential of neural precursors, and their asymmetric division, with or without self-renewal, are fundamental processes that govern the formation of a functional CNS in all animals. The Drosophila model system offers one of the best systems to explore this issue given the availability of mutations and genetic tools [1–5]. While we have made much progress in understanding the biology of stemness and asymmetric division of precursor cells [reviewed in ref. 6], almost nothing is known about the regulation of division potential, a process of great importance. Too few or too many divisions of precursor cells will leave the CNS aberrant and dysfunctional. We sought to use the development of the CNS in Drosophila as a paradigm to study both the regulation of division potential and how this is tied to precursor cell asymmetric division.
During neurogenesis in Drosophila, a large number of neurons are generated within the CNS via two types of precursor cells, each type undergoes a distinct kind of asymmetric division [1, 2]. The first type of precursor cell is the primary neuronal precursor or neuroblast (NB). NBs typically undergo a varying number of self-renewing asymmetric divisions, a fundamental property of all stem cells. The second type of precursor is the secondary neuronal precursor or ganglion mother cell (GMC). These cells undergo a single terminal asymmetric division without any self-renewal. This division generates two distinct post-mitotic neurons. Thus, these two types of divisions generate a large number of neurons of different identities from a few founder cells.
NB stem cells in the CNS divide a varying number of times during development, from one to as many as 18 (or perhaps even more), before becoming quiescent or post-mitotic or possibly die [2, 3]; some of the quiescent NBs re-enter the cell cycle during larval or pupal stages. At least one NB, known as MP2, while formed as a NB during the first of the five waves of NB delamination under the control of neurogenic and proneural genes similar to other NBs, it behaves as a GMC and divides only once to produce a pair of post-mitotic neurons [2, 7]. Some NBs are believed to behave similar to MP2 in their final round of division, thus, other NBs become quiescent to re-enter cell cycle in larval or pupal stages, and some may even die.
We have a good understanding of how a terminal asymmetric division of MP2 or a GMC generates two different neurons. This is achieved through asymmetric localization of determinants such as Inscuteable (Insc), Notch, Numb, Prospero, Neuralized, etc [7–17]. However, we do not know how a self-renewing asymmetric division is regulated. It appears that this is tied to the specification of the division potential of a specific NB. It is not known what genes restrict or specify NB division potential. Similarly, the mechanism and genes that restrict MP2 division to just one round are not known/understood. This is a significant problem in neurobiology as this timing and restriction or limit on the division potential of precursors form the basis for producing specific and correct number of neurons from flies to humans to form a functional CNS. We think that loss of function for genes involved in these processes will result in precursors such as MP2 and other NBs and GMCs undergoing additional rounds of division.
During the course of our work, we found that loss of function for midline, also known as lost in space (los) or extra [18–21] causes additional divisions of precursor cells, and therefore a candidate for regulating the division potential of precursors. Mid is a transcription factor belonging to the class of proteins known as T-box binding (Tbx) proteins. These proteins are highly conserved and have a 180–230 amino acid DNA-binding T-box domain. They bind to a 20-bp degenerate palindromic sequence called T-Box element (TBE) [22]. TBEs are highly variable in sequence, number and distribution within promoters and Tbx proteins diverge in their sequence preference as well [20]. Tbx proteins appear to repress transcription of genes [20, 23]. In vertebrates, haploinsufficiency for mouse brachyury (Tbx protein) and human TBX3 and TBX1 genes causes dominant phenotypes such as short tails/tailless, Ulnar-Mammary syndrome and DiGeorge syndrome, respectively [24, 25]. Upper limb malformation and congenital heart defects in Holt-Oram syndrome are due to haploinsufficiency for TBX5 [24, 26–28]. Thus, developmental processes appear to be sensitive to the levels of Tbx proteins.
In Drosophila, loss of function for mid causes cuticle defects in the midline region of the embryo, thus the name midline [18]. Loss of function for mid also causes defects in the lateral chordotonal axons, shorter and defasciculated dorsally routed axons in the peripheral nervous system (PNS)[19]. We have also shown that Mid is involved in identity specification of NBs and GMCs and regulate axon guidance via blocking the reiteration of the identity of rows of NBs within the ventral nerve cord [20, 21]. These results argue that Mid is involved in several important decision-making steps during CNS development.
In this work, we present evidence that Mid regulates the division potential of precursor cells such as MP2 and at least one GMC lineage. In MP2, Mid appears to couple restriction on self-renewing asymmetric division with terminal asymmetric division. This involves regulation of the cyclin E gene and localization of the Numb protein in precursor cells. Mid represses cyclin E by binding to the TBE within the cyclin E promoter. Cyclin E is the upstream regulator of the transition from G1 to S [29–33]. This is consistent with the finding that the temporal abundance of Mid in precursors changes in a dynamic manner, enabling it to carry certain temporal information. Our results allow us to build a model in MP2 where Mid peaks at a late stage MP2 and as a consequence, Cyclin E is downregulated. Thus, when MP2 divides into two post-mitotic neurons, Cyclin E level is kept below the threshold level required for entry to S-phase, and cells exit cell cycle. In the absence of Mid, cyclin E is de-repressed in MP2 and the high levels of Cyclin E pushes one or more progeny cells to enter S-phase, and thus, the cell cycle. Via an additional role for Mid in the localization of asymmetric determinants such as Numb, different progeny neurons are generated during lineage elaboration. While Mid represses cyclin E, this repression is not complete or an ON/OFF situation and this appears to have been achieved via two ways: one, by having variants of the Mid binding sites in the cyclin E promoter such that the repression is meant to prevent an over-expression of cyclin E but not abolish it, and two, by tightly regulating the levels of Mid itself, the mechanism for which is not yet known.
Results
Loss of function for Mid causes additional self-renewing asymmetric divisions in the MP2 lineage
MP2 is a primary precursor formed as an S1 NB in row 3, medial column around 4 hours post-fertilization (hpf)[2]. An MP2, unlike other NBs, undergoes only one terminal asymmetric division ~6.5 hpf, generating a dorsally, posteriorly located larger dMP2, and a ventrally, anteriorly located smaller vMP2 (Fig 1A). In mid los of function mutant embryos (mid1 midlos1, midextra or mid, H15df, which is the same as middf and removes both mid and its sister gene H15), we found that the MP2 lineage was affected. This was first observed with AJ96, an enhancer-trap marker for the MP2 lineage and is expressed in MP2, v and dMP2 (Fig 1) [34]. While only one MP2 per hemisegment was observed in 5 hpf mid mutant embryos (Fig 1B) as in wild-type control (Fig 1A), additional d and vMP2 neurons per hemisegment were observed in 10 hpf mid mutant embryos (Fig 1B). These neurons were one vMP2 and 2 dMP2s, or 2 vMP2 and 2 dMP2 or 2 vMP2 and one dMP2 (see also Table 1). Extra v/d MP2s could be generated via a symmetrical division of MP2 (Fig 1D), or formation of a second MP2 from the equivalence group or transformation of another NB into MP2. These instances will generate a four cells-phenotype (even number of neurons). However, in mid, the most frequent phenotype was a 3-cells phenotype, the first one generated via a self-renewing asymmetric division of MP2, and the two additional ones by the terminal asymmetric division of the self-renewed MP2 (Fig 1D).
We explored this issue in more detail by staining embryos fixed at different time-points to track the formation and division of an MP2 in a time-lapse manner. As shown in Fig 1C, we did not observe two MP2s but only one in the mutant as in wild-type control. But, the MP2 in the mutant divided slightly earlier than in control (~6 hpf versus 6.5 hpf). By 10 hpf there were 3 cells, 2 vMPs and one dMP2 in the mutant versus a d and a vMP2 in control (Fig 1C). These results suggest that the development of the MP2 lineage might be hastened in mid mutant embryos to generate additional progeny neurons via a self-renewing asymmetric division. The division patterns in mid embryos are summarized in Fig 1D.
Since AJ96 is expressed in MP2, but also in both d/vMP2s, we stained mid embryos fixed at different time-points with Achaete (Ac), which is expressed only in MP2 (Fig 2A–2C). The formation and identity specification of MP2 was normal in mid mutant embryos as judged by the expression of Ac with only one MP2 per hemisegment in 5 hpf mutant embryos (Fig 2A, Table 1). However, when mutant embryos that were older (~6.5 hpf) were examined, in about 4% of the hemisegments, two large Ac-positive MP2 cells next to each other were observed (Fig 2B). We examined the development of the MP2 lineage in wild-type and in mid mutant embryos by anti-Ac staining of a series of developmentally timed embryos. As shown in Fig 2C, in both the wild-type control and in the mutant an Ac-positive MP2 was observed in ~5 hpf. However, in the mutant, this MP2 appears to be dividing sooner than in the control (Fig 2C, ~6 hpf panels). In this asymmetrically elongated cell, the larger part had Ac-expression, whereas the other smaller part had no Ac-expression. By 7 hpf, while in the control the cell had divided with most of the AC expression in daughter cells absent, in the mutant, one of the two cells was larger and had a high level of Ac. By 9 hpf, the daughter neurons had lost Ac expression although, in the mutant, cells appeared still to retain some residual Ac. Taken together with the results from AJ96-staining (Fig 1), these results argue that MP2 undergoes a self-renewing asymmetric division in mid mutants.
Additional evidence for the self-renewing division came from staining mid mutant embryos with Odd-skipped (Odd) and Mab 22C10 (against MAP1B-like protein). Odd is expressed in MP2 and dMP2 but not in vMP2 [2]. However, 22C10 is expressed in MP2 shortly before its division and continues to be present in both v and dMP2 neurons. As shown in Fig 3A, in control, we could see an MP2 nearly completing its division (hemisegment on your right) to generate an anteriorly located and Odd-negative vMP2, and a posteriorly located Odd-positive dMP2. In the mutant, however, hemisegments where a dividing cell with one larger than the other and both expressing Odd were observed (Fig 3A, mid, left hemisegments). Even the nucleus appears to be larger in one of the two prospective cells (Fig 3A, lower panel). In older ~8 hpf embryos hemisegments with two vMP2s and one dMP2 could be observed (Fig 3B). We also observed hemisegments in 10 hpf mutant embryos with an Odd positive but 22C10-negative, therefore, an earlier stage MP2 (Fig 3C, arrow, left hemisegment). This hemisegment also had a vMP2 with its projection as well as a dMP2 (the projection is out of focus). These extra neurons send out their projection in the correct direction and fasciculate properly as intersegmental interneurons (Fig 3D), suggesting that these cells are unlikely mis-specified or with a “confused” identity.
We further examined the MP2 lineage for its division pattern with different combinations of markers. As shown in Fig 4A, hemisegments with 2 dMP2 and one vMP2, or 2 dMP2 and 2 vMP2 or 2 vMP2 and one dMP2 were observed. By inducing the UAS-mCD8-GFP transgene with ac-GAL4 driver to visualize neurons produced by MP2, multiple v and dMP2s were observed only in the mutant (Fig 4B). About 50–60 percent of the hemisegments had an MP2 phenotype in the mutant with preponderance for the formation of multiple dMP2 neurons (Table 1). It appears that in the mutant MP2 can also divide terminally and symmetrically into two dMP2s or 2 vMP2s, indicating a loss of asymmetric division (Fig 4A, middle and lower panels on your right; see also Table 1).
We also determined if mid affects GMC lineages since GMCs also undergo a single terminal asymmetric division to produce two post-mitotic neurons. We selected the first GMC of NB1-1 (GMC1-1a) since this lineage is well defined and its progeny neurons, aCC (anterior corner cell, a motor neuron that innervates muscle number 1) and pCC (posterior corner cell, an intersegmental interneuron), can be easily identified with different cell-specific markers [15]. As shown in Fig 5, in mid mutant embryos, staining with several different markers showed that while the penetrance was low, a GMC1-1a generating additional aCC and pCC neurons, was observed with preponderance for extra aCC neurons. It is likely that GMC1-1a undergoes a self-renewing asymmetric division similar to MP2, generating predominantly an aCC, but occasionally a pCC; the self-renewed GMC1-1a divides again but terminally to generate an aCC and a pCC. Since we also observed rarely two aCCs and two pCCs (Fig 5B), GMC1-1a may also divide symmetrically into two GMCs, each then generating an aCC and a pCC. These results indicate that a GMC can be susceptible to extra divisions similar to MP2 in mid mutant embryos.
Prospero is cytoplasmic in MP2 in mid mutant embryos
Previous results have shown that Prospero (Pros), a homeodomain protein with DNA-chromatin-binding activity [35], has an asymmetric and cortical localization in NBs (Fig 6A) but nuclear in GMCs (Fig 6B) [35, 36, 10] or in MP2 [10]. It has been proposed that cytoplasmic Pros NBs represents their self-renewing stem cell status, and nuclear localization signals an end to a stem cell status [37]. It is also possible that the cytoplasmic asymmetry of Pros localization is a method of segregating the protein to a committed GMC, where it becomes nuclear and functional as a DNA binding protein. Regardless, Pros localization could serve as an important marker for the self-renewing stem cell state of NBs.
In wild-type, Pros in MP2 is not only nuclear but appears to be mostly localized to the chromatin (Fig 6B, thick arrow). However, in the same age mid mutant embryos, Pros was not localized to chromatin, instead, it was cytoplasmic with a weak cortical distribution (Fig 6C, upper panels). This defect in Pros localization was observed in about 17% of the hemisegments (N = 300 hemisegments). We also observed MP2s where Pros was cortical and non-asymmetric as well as in the nucleus, but not on chromatin (Fig 6C, middle panels). A phenotype where Pros was cytoplasmic and cortical but also nuclear and chromatin-bound were also seen (Fig 6C, lower panels). These less severe localization defect was seen in about 11% of the hemisegments (N = 300 hemisegments). Whether this mis-localization of Pros in mid embryos is because of a changed division potential of MP2 or and Mid is involved in the proper localization of Pros is yet to be determined. However, these results further support the possibility that MP2s in mid mutants are multipotential stem cells and they undergo self-renewing asymmetric divisions similar to other NBs.
The identity of progeny neurons generated by the self-renewing asymmetric division of MP2 in mid is dependent on Numb localization
Previous results have firmly established that Numb and Notch play a central antagonistic role in the asymmetric division of MP2 [7, 17]. Wherever Numb is present at high concentrations, it blocks Notch signaling from specifying a vMP2 identity, allowing the two daughters to adopt a d and a v MP2 identity. This is achieved by the localization of Numb to the basal pole of MP2 prior to its division (Fig 7A; see also S2 Data), allowing it to be inherited by only one of the two daughters. In MP2 lineage, this mechanism allows the cell with Numb to fully differentiate into a dMP2 and the other into a vMP2 identity. We determined if the localization of Numb in MP2 is affected in mid mutant embryos. As shown in Fig 7B, in 5 hpf mid -mutant embryos, 38%+/-3% of the hemisegments had a non-asymmetric localization of Numb in MP2, with Numb uniformly spread along the cortex, versus 8.6%+/-2.3% in wild-type (Fig 7A). In 6 hpf, 32%+/-4% had non-asymmetric Numb in MP2 in mid embryos (Fig 7B) versus 4%+/-2% in the wild-type (Fig 7A). These MP2s are expected to produce dMP2s since they will be able to block the Notch-signaling. This is consistent with the finding that in majority of the affected hemisegments, dMP2s were formed compared to vMP2s (Table 1). The MP2 cell also appears to be dividing sooner in the mutant than in the control (Fig 7B). Furthermore, the division plane of MP2 in mid is not randomized or disrupted, but normal as could be seen in 6 hpf embryos (Fig 7B). This result also argues that MP2 self-renews in mid as opposed to a transformation of other neurons or NBs into MP2. We do not know how Mid regulates the asymmetric localization of Numb, perhaps by regulating factors that mediate Numb localization.
The expression of Mid in MP2 is highly dynamic
We next examined the expression of Mid in MP2. While we did not detect any Mid protein in an early stage MP2 either in the nucleus or in the cytoplasm (Fig 8A, arrowhead, note the definition of the nuclear membrane and a thin cytoplasm), low levels of Mid were detected prior to its division (Fig 8A, compare 5 hpf and 6 hpf panels). We further examined the expression of Mid in MP2 by confocal microscopy, double-staining embryos with anti-Mid and anti-β-galactosidase (β-gal) antibody for AJ96, which identifies MP2. As shown in Fig 8B–8D, low levels of Mid was detected only in MP2s that are considered late-stage and larger in size (see also Fig 8A). Analysis of multiple MP2 cells using ImageJ tool showed two populations of MP2s in terms of Mid expression, one that are smaller and with nearly undetectable levels of Mid and the other with larger with detectable levels of Mid (Fig 8C and 8D). Our ImageJ analysis of the expression pattern of Mid in MP2s across the cells using the plot profile analytic function indicated that the larger MP2 with Mid has a punctate profile (Fig 8D). Since the loss of function for mid causes MP2 defects, Mid, although the level is low, it is functionally significant and necessary to prevent the self-renewal of MP2. In contrast, a similar analysis of the expression of AJ96 showed that the expression profile is the same between the smaller and larger MP2 cells (Fig 8E).
An over-expression of Mid in MP2 blocks MP2 division
To determine if increasing the levels of Mid in MP2 in wild-type leads to division defects, we induced mid from a UAS-mid transgene with ac-GAL4 and stained 5–6 hpf embryos for AJ96, or Ac. About 14 hpf embryos were also stained for AJ96 or Odd. Ac stains MP2, AJ96 stains MP2, v and dMP2, and Odd stains MP2 and dMP2 (Odd also stains MP1, a distinct lineage). Staining 5–6 hpf embryos for Ac showed that about 10% of the hemisegments were missing an MP2 (N = 6 embryos; n = 107 hemisegments; S3 Data). With AJ96, about 11% of the hemisegments were missing MP2 (N = 6; n = 99) (Fig 9A; see also S3 Data). These results suggest that over-expression of Mid in MP2 likely interferes with its identity specification. Staining of 14 hpf embryos for AJ96 showed missing v/dMP2 pairs (Fig 9A) in about 14% of the hemisegments (N = 6, n = 116; S3 Data). As shown in Fig 9B, Odd-staining of 14 hpf embryos also showed hemisegments with missing dMP2 in about 27% of the hemisegments (N = 6, n = 107) (see S3 Data). With the staining of 14 hpf embryos for AJ96 or Odd, large Odd-positive cells of about 11–12 μm size, instead of v and dMP2 neurons could be observed in 10% -11% of the hemisegments (AJ96; N = 6, n = 116; Odd; N = 6, n = 107) (Fig 9A and 9B; see S3 Data). The size of the large cell is consistent with the size of an MP2. It would appear that in these hemisegments MP2 has not divided. The missing progeny neurons in some hemisegments are likely due to misspecification of the parent MP2. Being a transcription factor, a gain of function for mid causing identity misspecification is not surprising as it could inappropriately suppress or activate genes and prevent identity specification of cells [20, 21].
The above results show that although the UASxGAL4 system normally induces genes at a high level, the defects in the MP2 lineage with the over-expression of mid using this system was limited to about quarter of the hemisegments. To examine the reason for this, we double stained embryos that are over-expressing mid in MP2 for Mid and Ac. Only about 50% of the MP2s had a higher than normal levels of Mid (N = 60 hemisegments), the remaining MP2s had low or undetectable levels of Mid (Fig 9C). This argues that mid is regulated either at the post-transcriptional or post-translational levels (or both). Nonetheless, this possibility of regulation of Mid may explain the lack of a much stronger penetrance of the phenotypes in embryos over-expressing mid.
Cyclin E levels are upregulated in MP2 in mid mutant embryos
Given the above results, we sought to examine if mid affects the expression of cell-cycle genes, such as cyclins. Among the various cyclins, Cyclin E, which is a G1/S cyclin, is essential for the induction of S-phase and entry to cell cycle [29–33]. In Drosophila, Cyclin E is initially supplied as a maternal transcript. Sufficient protein is made to carry the embryo through the first 14 cleavage divisions. Subsequently, zygotic transcript is made for the next three cell division cycles. These three cycles are marked by the absence of a G1 phase: cells that exit mitosis go directly into the S phase. During these three cycles, cyclin E shows no cell-cycle-associated variation in transcription, but only following these three cycles [29–33].
Since one of the progenies of the MP2 division stays within the cell cycle in mid mutants, we examined the levels of Cyclin E in MP2. In wild-type, MP2 is formed around 4 hpf and it divides around 6.5 hpf. We stained wild-type control and mid mutant embryos that are 5.0–5.5 hpf, 5.5–6.0 hpf and 8.0–8.5 hpf with Cyclin E and Odd (Odd is to identify MP2 and dMP2). As shown in Fig 10A and 10B, the levels of Cyclin E in MP2 in 5.0–5.5 hpf embryos were about the same between wild-type and mid mutant embryos. Statistical analysis of the plot profile of the expression showed no statistically significant difference between the two (Fig 11A; S4 Data, S1 Statistics). Interestingly, there was a statistically significant difference in the expression of Odd between the two with the control having a higher level of Odd. Odd in wild-type embryos is not expressed in a newly formed MP2, but it can be detected after about 30 min of its formation. The lower levels of Odd in the mid mutant suggest that MP2 in the mutant may have retained certain properties of an early MP2. In 5.5–6.0 hpf embryos, the expression of Cyclin E in control is down regulated (Fig 10A; compare Fig 11A and 11B) and this down-regulation was statistically significant (S4 Data, S1 Statistics). However, the level of Cyclin E in MP2 in the mutant was increased in 5.5–6.0 hpf embryos, and this increase was statistically significant compared to the mutant at 5.0–5.5 hpf or to the wild-type control in both developmental stages (Figs 10B and 11B; S4 Data, S1 Statistics). The difference in the levels of Odd between the control and the mutant MP2 was minimal with no statistical significance (S4 Data, S1 Statistics). In post-mitotic dMP2 (and presumably also in vMP2), the level of Cyclin E was further down regulated in wild-type control (8.0–8.5 hpf panel, Figs 10A and 11C). A similar down regulation was also observed in mid mutant embryos, and this down-regulation was statistically significant compared to the 5.5–6.0 hpf mutant MP2s, but the difference in Cyclin E levels between the wild-type and the mutant dMP2 was not significant (Figs 10 and 11C; S4 Data, S1 Statistics). However, there was a statistically significant difference between the wild-type and the mutant in Odd expression with Odd being higher in the mutant (Figs 10, 11C, S4 Data, S1 Statistics). We have not investigated the significance of this dynamic Odd expression. Additional statistical comparisons of the levels between different time points within the group (wild-type control and mid) or between the groups of different time-points are given in Supplementary Information (S1 Statistics). In summary, these results show that there is an upregulation of Cyclin E in MP2 in mid mutants and argue that Mid functions as a repressor of cyclin E [see also ref. 20].
Mid binds to the TBE site in cyclin E promoter
We sought to explore the possibility that Mid represses cyclin E via binding to its promoter. This would require the presence of Mid-binding TBE in the promoter of cyclin E. The maternal promoter of cyclin E has two TBE sites and the zygotic promoter has one (Fig 12A and 12B). We focused on the zygotic promoter and since this TBE has the two parts of the consensus sequence running in opposite direction (Fig 12B), we determined if Mid can bind to this TBE using the gel shift assay. Purified Mid protein was incubated with P-32 labeled consensus TBE-sequence or the variant TBE sequence of the cyclin E zygotic promoter and the gel-shift assay was performed. As shown in Fig 12C, Mid binds the consensus TBE and the binding was dose-dependent; the Mid protein was also able to bind the cyclin E promoter-TBE, perhaps not as efficiently as the consensus site (a compact band with the consensus TBE versus a less compact or diffused band with the cyclin E TBE). Nonetheless, the ability of Mid to bind to the cyclin E TBE, taken together with the result that in mid embryos there is a de-repression of cyclin E expression (Fig 10), argues that Mid indeed represses cyclin E in MP2 via binding to its promoter, but this repression may not be necessarily complete as an ON/OFF switch (see Discussion).
A gain of function for cyclin E in MP2 causes the same self-renewing phenotype as loss of function for mid
Our results suggest that loss of function for mid results in the de-repression of cyclin E, which in turn maintains one or more of the progenies of the initial MP2 division within the cell cycle. In this scenario, ectopic expression of cyclin E in MP2 outside of the control of Mid should also result in the self-renewal of MP2. First, we induced the UAS-cyclin E transgene in MP2 in wild-type embryos using the MP2-specific ac-GAL4 driver. These embryos, aged about 9 hpf, were examined with Odd staining. As shown in Fig 13A (see also S5 Data), the over-expression cyclin E in MP2 generated additional dMP2 neurons. Second, we also induced cyclin E using a transgenic line carrying the cyclin E gene linked to the heat shock protein 70 gene promoter (Hs-cyc E). The transgene was induced briefly in embryos that are 5–7 hpf. After aging for another 3–4 hours, the d and vMP2 neurons were examined by staining these embryos for AJ96 and Odd (Fig 13B). As shown in Fig 10B (see also S5 Data), this induction resulted in the generation of extra d and vMP2 neurons. These phenotypes were strikingly similar to those produced by the loss of function for mid. Moreover, as in loss of function for mid, over-expression of cyclin E also produced predominantly extra dMP2 neurons (Fig 13C), indicating that the preference for dMP2 formation with the self-renewing asymmetric division of MP2 is common to both situations.
Discussion
There are very few cases in which we understand the control of the entry and exit of cells from the cell cycle. It can be argued that these controls are immensely important in the development of the nervous system, which is executed by stereotyped lineages coupled to regimented changes in developmentally important genetic players. Our data indicate that mid is one of the genes that may regulate entry/exit from the cell cycle of neural stem cells—to divide or not to divide or when to divide. Thus, mid may provide a much-needed entry point to understand these immensely important processes by tying the division potential of precursors to cyclin E, ultimately determining a certain number of neurons are produced from precursor cells during neurogenesis. Several previous studies have shown that mid plays a significant role in development and disease from flies to humans [19–21, 23–27, 38]. The results described in this paper add to the list of roles played by this important gene.
We argue that Mid mediates precursor cell exit from the cell cycle by regulating in part cyclin E (summarized in Fig 14). How does Mid do this? A critical amount of Cyclin E is essential for the cells to go from G1 (or G0) to S-phase [30–33]. Cyclin E level is down-regulated towards the end of S-phase. In MP2, this down-regulation of Cyclin E likely coincides with the up-regulation of Mid since Mid is present only at a later part of the MP2 cell cycle (Fig 14C). In mid mutant embryos, Cyclin E is not down regulated in MP2; cyclin E promoter has Mid-binding TBE and Mid binds to this TBE. These results argue that Mid acts as a repressor of cyclin E, which is also consistent with the finding that loss of function for mid produces the same MP2 phenotype as gain of function for cyclin E. One caveat is that when MP2 divides, the progeny has very little detectable Mid. How is the repression of cyclin E maintained in these cells? It may be that some other gene takes over the role of Mid, or that Mid has set up a chromatin “state” during the M-phase and that “state” guides the cell(s) to exit the cycle and become post-mitotic. Regardless, our results show that an inter-play between Mid and Cyclin E is part of the cellular strategy that keeps the progeny of MP2 from re-entering the cell-cycle. We want to point out that a gain of function for cyclin E in GMCs also induces GMCs to undergo self-renewing asymmetric divisions in the same fashion as MP2 does [39].
In mid mutant embryos, and likely also in cyclin E gain of function embryos, when MP2 divides, whichever cell randomly has a higher level of Cyclin E appears to maintain the MP2-like state and re-enters the cell cycle. The cell that has a lower level of Cyclin E becomes committed to a differentiation pathway (Fig 14). If both the progeny have higher levels of Cyclin E, which is above the threshold required to enter cell cycle, we think that both will retain the MP2 identity for at least one additional division, resulting in a 2 d and 2 vMP2 phenotype (Fig 4A). We do not know if an asymmetric inheritance of Cyclin E occurs during division, or in one of the daughters Cyclin E is selectively degraded in line with its differentiation state or future. A similar situation exists for Odd expression in MP2 lineage as well. When MP2 divides, Odd is either not segregated to the presumptive vMP2, or it gets very quickly degraded in that cell (Fig 3A).
A loss of function for mid up regulates Cyclin E, but it also causes the retention of MP2 identity in one of the daughters of MP2. This daughter retains a strong, MP2-like Ac expression and is also larger similar to an MP2. Thus, this is not simply a matter of moving through the offspring’s G1 checkpoint. Since Mid is known to have a role in identity specification [18, 20, 21], its expression in late MP2 may be involved not only in the down regulation of cyclin E but also to prevent its self-renewal as an MP2. This is further supported by the finding that in mid mutants, Pros in MP2 does not remain localized to chromatin in the nucleus but is cytoplasmic similar to other NB stem cells (Fig 6). Furthermore, Numb localization in MP2 in the mutant is non-asymmetric (Fig 7). It may be that non-nuclear/chromatin Pros and non-asymmetric Numb plays a role in conferring a self-renewing capability to MP2 in mid mutants. Mid might also regulate genes necessary for Pros and Numb localization, or these affects might be a consequence of the change in MP2 division potential. We would also note that an upregulation of Cyclin E in mid mutants might itself mediate the retention of MP2 identity by one of the daughters since over-expression of cyclin E outside its normal controls leads to the same MP2 lineage phenotype as loss of function for mid. The significance of our results described here extend beyond the generation of a few extra neurons in one NB lineage and one GMC lineage, it provides a window as to how a large number of neurons in specific lineages or regions would have been generated during evolution, a process by which humans acquired a significantly larger neocortex compared to our immediate relatives in the evolutionary tree.
Regulating the number of cell divisions of precursor cells
It is not known which genes or mechanisms restrict the division potential of NBs or GMCs. The same mechanism may operate in these precursor cells to limit their division potential. Mid appears to be a player in this process. One of the questions is whether the mechanism involves an elapsed developmental period (time-elapsed, and unidirectional), or is it the number of divisions a parent cell counts. The elapsed-time model will require a sequential and time-sensitive build-up of regulators/events that are independent of cell division. The cell division counting mechanism will rely on the number of cell divisions that occurs for events or gene expression changes to take place. There is evidence that events and gene expressions do not strictly follow elapsed time but dependent on cell division [40, 41]. The Drosophila embryonic nerve cord is organized into hemisegments, and each hemisegment is more or less the same as the other with the same set of neurons. But there is heterogeneity in the timing of cell division of the same lineage between hemisegments. The gene expression also varies accordingly between hemisegments. Thus, unless the measurement of the time itself varies between cells/lineages (or hemisegments), there may not be a precise measuring of time-elapsed that regulates events and gene expression programs. The gene expression program in a NB changes over time, and this change is NB-division-dependent [40, 41]. We also think that there may be a unidirectional, elapsed time mechanism with some plasticity, and it may interact with the division-counting mechanism to prevent an uncontrolled cell division of precursor cells.
Mid-regulation of asymmetric division of precursor cells
Mid appears to affect both the self-renewing asymmetric division as well as the terminal asymmetric division. For example, MP2 that self-renews in mid mutants also generates extra post-mitotic neurons, whose identity is dependent on the localization of determinants such as Numb (Figs 1–4). We do not believe these extra neurons are generated from a second NB that has adopted an MP2 identity (or from the MP2-equivalence group, as in neurogenic mutants) since mostly one MP2 is seen in the mutant (Figs 1C, 2A and 2C). We did find rarely two MP2s (Fig 2B), but they appear to be from the symmetrical division of MP2 into two MP2s. Furthermore, a duplication of MP2 due to the transformation of another NB to MP2 or a second MP2 forming from the equivalence group would generate even-numbered progeny neurons. In mid, the majority of hemisegments generate odd-numbered neurons (Figs 1–4; Table 1). The cytoplasmic Pros localization in MP2 in mid (Fig 6C) certainly confirms that MP2 has adopted a NB stem cell identity. These arguments also apply to GMC lineages, where we found, for example, GMC1-1a generating odd numbered progeny neurons (Fig 5). In how many NB/GMC lineages Mid regulates the division potential is not known, but based on the expression pattern, we think that the division of a subset of NBs/GMCs is subjected to Mid regulation. Finally, a transformation of epithelial cells to neurons in mid is not likely since we do not see holes in the cuticle [18, 21]. The partial penetrance of the defects in mid mutants might be arising from a partial redundancy for the pathway or more likely the mid gene since the fly genome has about 8 known Tbx genes.
Loss of function for mid can affect NB identity [21]. Is it possible that MP2 adopts a different NB identity in mid mutants? The answer is unlikely since MP2 in the mutant expresses markers that are specific for MP2 and not for other NBs. They also produce progeny neurons specific to the lineage. For the same reason, we do not believe an MP2 or its progeny in mid embryos are “confused”. A parent cell that has confused or rather has an altered identity will produce neurons specific to the identity that the MP2 has transformed into, or a new identity from a confused state.
The role of Mid in the terminal asymmetric division, i.e., what will be the identity of the progeny neuron, appears to be tied to the asymmetric segregation of Numb. Previous results have shown that Numb segregates to the basal pole of MP2 and when MP2 divides, only the presumptive dMP2 inherits Numb [7]. The function of Numb is to block Notch signaling from specifying a vMP2 identity [7] and Notch signaling appears to begin acting on MP2 cell itself before its division [17]. In mid mutants, Numb is frequently seen non-localized and distributed throughout the cortex of MP2 (Fig 7B) instead of its normal basal pole localization (Fig 7A), As a result, one can observe a dividing MP2 with both cells inheriting Numb in mid mutants. In such hemisegments, asymmetric self-renewal of MP2 likely produces a dMP2. But, in those hemisegments that produce vMP2s, we suspect Numb localization is asymmetric or absent. In either case, the apical/basal plane of division of MP2 does not seem to be affected (Fig 7B). Additionally, a non-localization of Numb has not been associated with randomization or disruption of plane of division, it only causes progeny neuronal identity switch, or identity misspecification [see ref. 7, for example]. We think that mid affects Numb localization indirectly. Being a transcription factor, it could alter the expression of any of the genes that are part of the Numb-localization mechanism. It could also affect numb expression directly, albeit in a partially redundant manner.
Mid and Cyclin E relationship in MP2
The entire regulation of Cyclin E by Mid is intriguing. For one thing, evolution appears to design mutant or variant TBE sequence in the cyclin E promoter, especially in the zygotic promoter of cyclin E. In gel shift assays, the binding we saw with the zygotic cyclin E TBE appears to be weaker and less discrete compared to the consensus TBE sequence. The evolutionary goal perhaps at play in MP2 is not to repress cyclin E entirely but do it just enough so that the level does not go up excessively. This may be for a reason as evidenced by the finding that when the level of Cyclin E is up-regulated, either in mid mutants (Figs 10 and 11) or when cyclin E is over-expressed (Fig 13), the lineage generates extra neurons. We did not use cyclin E mutants in our studies since a loss of function for cyclin E appears to alter the identity of NBs [42]. In the 1960s, Hayflick found that mammalian somatic cells divide 40–60 times and then undergo apoptosis. This is called the Hayflick limit [43]. Precursor cells that give rise to the nervous system do not seem to obey the Hayflick limit. Thus, in Drosophila, for example, neuronal precursors can divide as many as 1200. The extent of cell proliferation may be even greater during the development of our own brain. A Mid-Cyclin E like mechanism such as the one we have shown here might allow these neural cells to escape Hayflick’s limit.
Materials and methods
Fly stocks, genetics
mid mutant alleles used were mid1, mid2, los1 and a deficiency that removes both mid and its sister gene, H15 (mid H15df or middf; Bl# 7498; breakpoints: 25D5-25E6). The other lines used were: ac-GAL (BL#: 8715), UAS-mCD8-GFP (mouse CD8-GFP transgene under UAS; BL# 41803), UAS-cyclin E (BL# 4781), Hs-cyclin E (BL# 59056), UAS-mid [20], AJ96-LacZ [7] RN2 (eve)-GAL4 [21], UAS-tau-LacZ and UAS-tau-GFP [21]. Additional lines used: ftz-GAL4, wg-GAL4 (Kyoto#4918), arm-GAL4 (BM#1561), elav-GAL4 (BM# 8765 or BM#8760), sim-GAL4 (BL#9150). For wild type, we used Oregon R flies. Mutant lines were balanced using GFP-bearing balancer chromosomes or LacZ-bearing balancers to facilitate identification of the mutant genotype. Standard genetics were used to obtain combinations of genotypes when needed.
Immunohistochemistry
The embryo collection, fixation and immunostaining were performed according to the standard procedures. Briefly, for immunolabeling, embryos were washed thoroughly with running water, dechorionated with 50% bleach, rinsed with running water and then with phosphate-buffered saline containing Triton X-100 (Sigma) (0.1%), and fixed with n-heptane (Fisher Scientific) and 37% formaldehyde (Fisher Scientific) mixed in a 1:1 ratio for 2 min (immunofluorescence labeling) or for 6 min (immunohistochemical labeling). Vitelline membranes were removed by a rapid (~20 seconds) wash with methanol (Fisher Scientific). Embryos were processed immediately. The following antibodies were used: anti-Mid (rabbit, 1:50; ref. 20), anti- Fas II (mouse, 1: 5; DHSB), 22C10 (mouse, 1:1; DHSB), anti-Achaete (mouse, 1:4; source: DHSB), anti-GFP (mouse, 1:100, Abcam, mAb9F9.F9), anti-Odd (guinea pig, 1:100, John Reinitz), anti-Cyclin E (1:4; source: Helena Richardson), anti-β-galactosidase (mouse, 1:500; Cappel), Eve (1:2000; source: Manfred Frasch) and Numb (rabbit, 1:100; Source: Jim Skeath, Chris Doe), Numb (guinea pig, 1:50; source: Jim Skeath), anti-β-galactosidase (rabbit; 1:3000, Invitrogen, A-11132, or mouse, 1:400; DSHB, 40-1a). For color visualization, either AP-conjugated or HRP-conjugated secondary antibodies were used. For light microscopy, secondary antibodies conjugated to alkaline phosphatase (rabbit, 1:200, Pierce, 31341) or horseradish peroxidase (HRP; rabbit, 1:200, Pierce, 31460) were used. Alkaline phosphatase was detected using 5-bromo-4- chloro-3-indolyl-phosphate and nitro blue tetrazolium (Promega, S3771). HRP was detected with diaminobenzidine (Sigma, D4418). For confocal visualization, secondary antibodies conjugated to Cy5 (rabbit, 1:400, Invitrogen, A10523), fluorescein isothiocyanate (mouse, 1:50, Invitrogen, 62–6511), Alexa Fluor 488 (rabbit or mouse, 1:300, Invitrogen, A-11008 or A-11001), or Alexa Fluor 647 (rabbit or mouse, 1:300, Invitrogen, A-21245 or A-21236) or Alexa Flour 488 (1:400) were used.
Hs-cyc E experiments
AJ96-lac Z transgenic line was introduced to Hs-cyc E transgenic background and these Hs-cyc E; AJ96 embryos were collected for 2 hours at room temperature, allowed to develop for 5 hours at room temperature (5–7 hpf embryos). These embryos were then shifted to 30 0C for 30 min, and further allowed to develop for 3–4 hours before fixing and staining for Odd or AJ96 and Odd. The cells were visualized using confocal microscopy.
Gel shift assay
The consensus TBE and the TBE from the cyclin E zygotic promoter were purchased as double-strand oligos from IDT (Integrated DNA Technologies, San Diego, CA). The double-stranded oligos were end-labeled with [32P]-ATP with T4 polynucleotide kinase and incubated the Mid protein tagged with 6x Histidine (His) at the C-terminus (MidHis) at different concentrations (0.04 μg, 0.2 μg and 0.4 μg). The mid-his fusion gene was expressed in E. coli BL21-CodonPlus (Stratagene) and the native protein was affinity purified using Ni-NTA resin columns (QIAGEN standard protocol). About 30 pg of the labeled probe and various amounts of the MidHs protein were allowed to interact for 30 minutes on ice in binding buffer (10 mM Tris–HCl, pH 7.5, 50 mM NaCl, 1 mM MgCl2, 0.5 mM DIT, 50 μg/ml poly dl-dC and 4% glycerol) in a final volume of 30μl. The products of the binding reaction were separated using non-denaturing acrylamide: bis-acrylamide gel (4:0.05%) in low ionic strength buffer (6.7 mM Tris, pH 7.5; 1 mM EDTA, pH 7.5, and 3.5 mM sodium acetate) at 4°C. The gel was dried and visualized by autoradiography.
ImageJ analysis
We used plot profile function to determine the level-distribution profile of Mid and AJ96 (Fig 8) or Cyclin E and Odd (see Figs 10 and 11). The following steps were adopted: for Fig 8, images were saved as 200-pixels/Inch resolution in Adobe Photoshop, and then converted into JPEG files. The JPEG images were opened with ImageJ with the following measurement setup: Area, mean gray value and integrated density were set under Measurements. Using the rectangle function, the area in the cell was defined and under Analyze, the Plot profile function was used for analysis. Since the expression of Mid in one group of MP2 was baseline, we did not convert the gray values into numbers, therefore no statistics were applied (a 0 versus >0 situation). For the analysis of Cyclin E and Odd in MP2 and dMP2 between control versus mid at different developmental time points (Figs 10 and 11), ImageJ analysis was done using the plot profile function. The images were set at resolution 300-Pixels/Inch and 3660 Pixels, saved as JPEG files for ImageJ analysis. See Supplementary Information for the dataset and statistical analysis (S4 Data; S1 Statistics).
Statistics
We used Two Sample T-Test (Welch’s T-Test) to analyze the means between groups of datasets (http://www.statskingdom.com/150MeanT2uneq.html). The details and the analyses are given Supplementary Information (S5 Data).
Supporting information
S1 Data [docx]
Supporting information for Figs – and .
S2 Data [docx]
Supporting information for .
S3 Data [docx]
Supporting information for .
S4 Data [docx]
Supporting information for Figs and .
S5 Data [docx]
Supporting information for .
S1 Statistics [docx]
Statistical analysis of the datasets from Figs and .
Zdroje
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