sloppy paired 1
Transcription of slp is first detected in the head, in a gap-like pattern during the syncytial blastoderm. Seven primary segmental stripes appear during the cellular blastoderm followed by seven additional secondary stripes between the primary stripes. By germ band expansion [Images], expression in the head is more complex, due to the development of the different head primordia. The metameric pattern fades at germ band retraction and transcript appears in the border of the dorsal epidermis, during dorsal closure. slp2 lags slp1 in many of these expression features (Grossnicklaus, 1992) .
The Drosophila brain develops from the procephalic neurogenic region of the ectoderm. About 100 neural precursor cells (neuroblasts) delaminate from this region on either side in a reproducible spatiotemporal pattern. Neuroblast maps have been prepared from different stages of the early embryo (stages 9, 10 and 11, when the entire population of neuroblasts has formed), in which about 40 molecular markers representing the expression patterns of 34 different genes are linked to individual neuroblasts. In particular, a detailed description is presented of the spatiotemporal patterns of expression in the procephalic neuroectoderm and in the neuroblast layer of the gap genes empty spiracles, hunchback, huckebein, sloppy paired 1 and tailless; the homeotic gene labial; the early eye genes dachshund, eyeless and twin of eyeless; and several other marker genes (including castor, pdm1, fasciclin 2, klumpfuss, ladybird, runt and unplugged). Based on the combination of genes expressed, each brain neuroblast acquires a unique identity, and it is possible to follow the fate of individual neuroblasts through early neurogenesis. Furthermore, despite the highly derived patterns of expression in the procephalic segments, the co-expression of specific molecular markers discloses the existence of serially homologous neuroblasts in neuromeres of the ventral nerve cord and the brain. Taking into consideration that all brain neuroblasts are now assigned to particular neuromeres and individually identified by their unique gene expression, and that the genes found to be expressed are likely candidates for controlling the development of the respective neuroblasts, these data provide a basic framework for studying the mechanisms leading to pattern and cell diversity in the Drosophila brain, and for addressing those mechanisms that make the brain different from the truncal CNS (Urbach, 2003).
The cephalic gap genes are expressed in large domains of the procephalon and play a crucial role not only in the patterning of the peripheral ectoderm, but also in regionalizing the brain primordium. The segmental organization of the Drosophila brain is based on the expression pattern of segment polarity and DV patterning genes. To see whether the cephalic gap genes respect the neuromeric boundaries segment polarity and DV patterning genes, and to provide a basis for studying their potential role in the formation or specification of brain precursor cells, the expression was studied of orthodenticle, empty spiracles, sloppy paired 1, tailless, huckebein, and hunchback in the developing head ectoderm, as well as in the entire population of identified NBs during stages 9-11 (Urbach, 2003).
The sloppy paired (slp) locus contains the two related genes slp1 and slp2. slp1, which acts as a head gap gene, plays a predominant role in head formation, while slp2 is largely dispensable. In the trunk neuroectoderm, where slp1 has a function as a pair-rule and segment polarity gene, it is segmentally expressed in neuroectodermal stripes as well as in NBs of row 4 and 5. This segmental appearance of slp1 expression is found to be conserved in parts of the procephalon. In the blastoderm, Slp1 protein is detected in a large domain of the procephalon anlage, which subsequently diminishes in its anterior/ventral part. As a result, only the posterior half of the original slp1 domain remains as a circumferential ring ('head stripe') and gets separated from the anterodorsal part ('head cap'). To follow the dynamics in the Slp1 expression pattern, Slp1/En double labelling was examined during stages 8-11. The 'head stripe' corresponds to the slp1 stripe of the prospective mandibular segment, and the posterior part of the 'head cap' to the Slp1-positive stripe in the prospective antennal segment (slp1 as). At the beginning of gastrulation, a new Slp1 ectodermal spot in the anterodorsal procephalon is observed; this spot later becomes part of the labral ectoderm. In addition, at stage 9, three new ectodermal domains become detectable: one stripe anterior to the en intercalary stripe belonging to the intercalary segment, and two small spots in the region of the ocular segment (anterior to the en head spot). Except for the labral domain, the slp1 domains contribute NBs to the brain. Thus, slp1 is segmentally expressed in the procephalic neuroectoderm and subsets of brain NBs, resembling the situation in the trunk. At stage 11 patchy expression of Slp1 becomes detectable within the ocular and labral ectoderm and in some underlying ocular and labral NBs. Some of these NBs initiate slp1 expression after delamination; e.g. Pcv6 and Pcd2 delaminate at stage 9 and do not express slp1 before stage 11. Slp1 expression is observed in the brain until the end of embryogenesis (Urbach, 2003).
Very little information is available about gene expression during the larval period, a developmental interval critical to the formation of the adult. To what extent does gene expression during this period resemble that in the embryonic stages, and how does gene expression during the larval period contribute to segment polarity in the adult? In fact, all the genes expressed during embryonic segment polarity also play a similar role in the formation of the adult. Cells destined to form the cuticle of the adult abdomen are present as clusters of small, non-dividing diploid cells (the anterior dorsal, posterior dorsal and ventral histoblast nests) located at stereotyped postions in the larval epidermis. These cells, just as do their embryonic counterparts, express engrailed, hedgehog, wingless, patched, cubitus interruptus and sloppy paired in a stereotyped manner dependent on their positions within each segment. Each
segment is subdivided into an anterior (A) and posterior (P) compartment, distinguished by activity of the selector gene engrailed (en)
in P but not A compartment cells. The ventral epidermis of each abdominal segment forms a flexible cuticle, the pleura, with a small plate of sclerotised cuticle, the sternite, centered on the ventral midline. The pleura is covered with a uniform lawn of hairs, all pointed posteriorly, whereas the sternite contains a stereotyped pattern of bristles. Posterior compartments are to a large degree devoid of hairs and bristles, while the sternite cuticle of the A compartment consists of an anterior-to posterior progression of six types of cuticle distinguished by ornamentation and pigmentation. Just anterior to the posterior compartment, A6 is unpigmented, with hairs and none
of the larger ornaments called bristles. A5 is darkly pigmented with hairs and bristles of large size. A4 and A3 are darkly and lightly pigmented respectively with moderately sized hairs and bristles. A2 is lightly pigmented with hairs, and A1, adjacent to the next more anteriorly located "posterior" compartment is unpigmented without hairs (Struhl, 1997a).
Hedgehog (Hh), a protein secreted by engrailed expressing P compartment cells, spreads
into each A compartment across the anterior and the posterior boundaries to form opposing concentration gradients that organize cell
pattern and polarity. Anteriorly and posteriorly situated cells within the A compartment respond in distinct ways to Hh:
they express different combinations of genes and form different cell types. patched is expressed at both boundaries. patched is expressed in a graded fashion within each stripe, just anterior to each P compartment. ci peaks at high level in those cells abutting Hh- secreting cells of the P compartment and declines progressively in cells further away. wingless is also expressed in this domain and sloppy paired is expressed in the same region as wingless. decapentaplegic is expressed only in the ventral pleura in those A compartment cells neighboring P compartment cells within the same segment. dpp is not expressed immediately behind posterior compartments (Struhl, 1997).
The brain consists of various types of neurons that are generated from neural stem cells; however, the mechanisms underlying neuronal diversity remain uncertain. A recent study demonstrated that the medulla, the largest component of the Drosophila optic lobe, is a suitable model system for brain development because it shares structural features with the mammalian brain and consists of a moderate number and various types of neurons. The concentric zones in the medulla primordium that are characterized by the expression of four transcription factors, including Homothorax (Hth), Brain-specific homeobox (Bsh), Runt (Run) and Drifter (Drf/Vvl), correspond to types of medulla neurons. This study examined the mechanisms that temporally determine the neuronal types in the medulla primordium. For this purpose, transcription factors were sought that are transiently expressed in a subset of medulla neuroblasts (NBs, neuronal stem cell-like neural precursor cells) and identified five candidates [Hth, Klumpfuss (Klu), Eyeless (Ey), Sloppy paired (Slp) and Dichaete (D)]. The results of genetic experiments at least explain the temporal transition of the transcription factor expression in NBs in the order of Ey, Slp and D. The results also suggest that expression of Hth, Klu and Ey in NBs trigger the production of Hth/Bsh-, Run- and Drf-positive neurons, respectively. These results suggest that medulla neuron types are specified in a birth order-dependent manner by the action of temporal transcription factors that are sequential ly expressed in NBs (Suzuki, 2013).
In the embryonic central nervous system, the heterochronic
transcription factors suchas Hb, Kr, Pdm, Cas and Grh are
expressed in NBs to regulate the temporal specification of
neuronal identity. They regulate each
other to achieve sequential changes in their expression in NBs without cell-extrinsic
factors. However, expression of the embryonic heterochronic genes was not detected in the medulla
NBs.Instead this study found that Hth, Klu, Ey, Slp and D are
transiently and sequentially expressed in medulla NBs. The
expression of Hth and Klu was observed in lateral NBs, while that
of Ey/Slp and D was observed in intermediate and medial NBs,
respectively. These observations suggest that the expression of heterochronic transcription factors changes sequentially as
each NB ages, as observed in the development of the embryonic
central nervous system (Suzuki, 2013).
This study demonstrates that at least three of the
temporal factors Ey, Slp and D regulate each other to form a
genetic cascade that ensures the transition from Ey expression to D
expression in the medulla NBs. Ey expression in NBs
activates Slp, while Slp inactivates Ey expression. Similarly, Slp
expression in NBs activates D expression, while D inactivates Slp
expression. In fact, the expression of Slp is not strong in newer NBs
in which Ey is strongly expressed, but is up regulated in older NBs
in which Ey is weakly expressed in the wildtype medulla. A
similar relationship is found between Slp and D, supporting the
idea that Ey, Slp and D regulate each other's expression to control
the transition from Ey-expression to D-expression. In the
embryonic central nervous system, similar interaction is mainly
observed between adjacent genes of the cascade hb-Kr-pdm-cas-grh, and this concept may also be applied to the medulla primordium. The expression pattern and function of Ey, Slp
and D suggest that they are adjacent to each other in the cascade of
transcription factor expression in medulla NBs (Suzuki, 2013).
However, no such relationship was found between Hth, Klu and
the other temporal factors.The sequential expression of Hth and
Klu could be regulated by an unidentified mechanism that is
totally different from the genetic cascade that controls the transition through Ey-Slp-D. Or, there might be unidentified temporal factors that are expressed in lateral NBs which act upstream of Hth
and Klu to regulate their expression. It is necessary to identify additional transcription factors that are transiently expressed in medulla NBs (Suzuki, 2013).
The expression of concentric transcription factors in the
medulla neurons correlates with the temporal sequence of neuron
production from the medulla NBs (Hasegawa, 2011). In the
larval medulla primordium, the neurons are located in the order of
Hth/Bsh-, Run- and Drf-positive cells from inside to outside, and
these domains are adjacent to each other (Hasegawa, 2011).
Given that NBs generate neurons toward the center of the developing medulla, Hth/Bsh-positive neurons are produced at first, and
then Run-positive and Drf-positive neurons. Thus Hth/Bsh, Run and Drf were used as markers to examine roles of Hth, Klu, Ey, Slp and D expressed in NBs in specifying types of medulla neurons.
The continuous expression of Hth and Ey from NBs to neurons
and the results of clonal analyses that visualize the progeny of NBs
expressing each one of the temporal transcription factors suggest
that the temporal windows of NBs expressing Hth, Klu and Ey
approximately correspond to the production of Hth/Bsh-, Run- and
Drf- positive neurons, respectively. Indeed, the results of
the genetic study suggest that Hth and Ey
are necessary and sufficient to induce the production of Hth/Bsh-
and Drf-positive neurons,respectively (Hasegawa, 2011,
2013). Ectopic Klu expression at least induces the produc tion of Run-positive neurons (Suzuki, 2013).
Slp and D expression in NBs may correspond to the temporal
windows that produce medulla neurons in the outer domains of
the concentric zones, which are most likely produced after the
production of Drf-positive neurons. The results at least
suggest that Slp is necessary and sufficient and D is sufficient to
repress the production of Drf-positive neurons.
Identification of additional markers that are expressed in the outer
concentric zones compared to the Drf-positive domain would be
needed to elucidate the roles of Slp and D in specification of
medulla neuron types (Suzuki, 2013).
D mutant clones did not produce any significant phenotype
except for derepression of Slp expression in NBs. Drf
expression in neurons was not affected either. Since D is a
Sox family transcription factor, SoxN, another Sox family transcription factor, is a potential candidate molecule that acts together
with D in the medulla NBs. However, its
expression was found in neuroepithelia cells and lateral NBs that overlap with
Hth-positive cells but not with D-positive cells.
All the potential heterochronic transcription factors examined
in this study are expressed in three to five cell rows of NBs.
Nevertheless, one NB has been observed to produce one Bsh-
positive and one Run-positive neuron (Hasegawa, 2011).
Therefore, the expression pattern of the heterochronic transcription factors is not sufficient to explain the stable production of one
Bsh-positive and one Run-positive neuron from a single NB.The
combinatorial action of multiple temporal factors expressed in NBs
may play important roles in the specification of Bsh- and Run-
positive neurons (Suzuki, 2013).
Another possible mechanism that guarantees the production of
a limited number of the same neuronal type from multiple rows of
NBs expressing a temporal transcription factor could be a mutual
repression between concentric transcription factors expressed in
medulla neurons. For example, Hth/Bsh, Run and Drf may repress
each other to restrict the number of neurons that express either of
these transcription factors. However, expression of Run and Drf
was not essentially affected in hth mutant clones and in clones
expressing Hth (Hasegawa, 2011). Similarly, expression of
Hth and Drf was not essentially affected in clones expressing run
RNAi under the control of AyGal4, in which Run expression is
eliminated. Hth and Run expression was not affected in drf mutant clones
(Hasegawa, 2011). These results suggest that Hth/Bsh, Run and Drf do not essentially regulate each other during the formation of concentric zones in the medulla (Suzuki, 2013).
During embryonic development, the heterochronic genes
that are expressed in NBs (hb-Kr-pdm-cas-grh) are maintained and
act in GMCs to specify neuronal type. Similarly, Hth and Ey are continuously
expressed from NBs to neurons, suggesting that their expression
may also be inherited through GMCs (Hasegawa, 2011).
However, this type of regulatory mechanism may be somewhat
modified in the case of Klu, Slp and D (Suzuki, 2013).
Klu is expressed in NBs and GMCs, but not in neurons.
Slp and D are predominantly detected in NBs and neurons
visualized by Dpn and Elav, respectively. Occasionally, however, expression of D was found in putative GMCs, which are situated between NBs and neurons. Additionally, both D-positive and D-negative cells were found among Miranda-positive GMCs. Slp expression was not found
in Miranda-positive GMCs. Finally, D is expressed in
medulla neurons forming a concentric zone in addition to its
expression in medial NBs. However, D expression was abolished in
slp mutant NBs but remained in the mutant neurons,
suggesting that D expression in medulla neurons is not inherited
from the NBs. These results suggest that Slp and D expression are
not maintained from NBs to neurons and that not all the temporal
transcription factors expressed in NBs are inherited through GMCs.
However, it is possible to speculate that Klu, Slp and D regulate
expression of unidentified transcription factors in NBs that are
inherited from NBs to neurons through GMCs (Suzuki, 2013).
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sloppy paired 1:
Biological Overview
| Evolutionary Homologs
| Regulation
| Developmental Biology
| Effects of Mutation
date revised: 12 April 2018
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