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The Journal of Neuroscience, April 15, 2003, 23(8):3118
BRIEF COMMUNICATION
Small GTPase Cdc42 Is Required for Multiple Aspects of Dendritic MorphogenesisEthan K. Scott, John E. Reuter, and Liqun Luo Department of Biological Sciences, Stanford University, Stanford, California 94305-5020
ABSTRACT
TOP
ABSTRACT
Introduction
The study of dendritic development in CNS neurons has been hampered by a lack of complex dendritic structures that can be studied in a tractable genetic system. In an effort to develop such a system, we recently characterized the highly complex dendrites of the vertical system (VS) neurons in the Drosophila visual system. Using VS neurons as a model system, we show here using loss-of-function mutations that endogenous Cdc42, a member of Rho family of small GTPases, is required for multiple aspects of dendritic morphogenesis. Cdc42-mutant VS neurons display normal complexity but increased dendritic length compared with wild type and have defects in dendrite caliber and stereotyped dendritic branch positions. Remarkably, Cdc42 mutant neurons also show a 50% reduction in dendritic spine density. These results demonstrate that Cdc42 is a regulator for multiple aspects of dendritic development.
Key words: Drosophila; vertical system; dendrites; dendritic spines; Rho GTPases; actin cytoskeleton
Introduction
The complex and characteristic structures of dendrites are a crucial part of the neuronal architecture that underlies brain function; as such, their development has been a focal point of recent research (for review, see McAllister, 2000
; Cline, 2001
The Rho family of small GTPases, notably RhoA, Rac, and Cdc42, are key regulators of the actin cytoskeleton in response to extracellular cues (Etienne-Manneville and Hall, 2002
Studies involving dominant mutant expression, although informative, have a number of caveats. Dominant-negative Rho GTPase mutants are believed to act by titrating guanine nucleotide exchange factors (Ridley et al., 1992
We therefore sought to evaluate the function of endogenous Rho GTPases in dendritic morphogenesis using loss-of-function mutants. Because of the ubiquitous function of Rho GTPases in development, we developed a genetic mosaic method by which we could generate a very small population of uniquely labeled homozygous mutant neurons in an otherwise heterozygous and unlabeled brain (Lee and Luo, 1999
Materials and Methods
Drosophila were grown on standard media at 25°C. During clonal analysis, larvae hatched over a 2 hr interval were moved to vials containing 10 ml of food and kept at a concentration of 80 per vial. Mitotic recombination was induced via heat shock (40 min in a 37°C water bath, 30 min at room temperature, and 40 min in 37°C water bath) at 2 and 3 d after hatching. Adult female flies between 2 and 5 d after eclosion were dissected, fixed, and stained as described previously (Lee et al., 1999
A Bio-Rad (Hercules, CA) MRC 1024 laser scanning confocal microscope and the Laser Sharp image collection program were used. Images were prepared using Adobe Photoshop (Adobe Systems, San Jose, CA). Three-dimensional traces of the dendrites were produced from confocal stacks using MicroBrightField (Colchester, VT) Neurolucida software (Scott et al., 2002
Results
Loss-of-function Cdc42 mutants (Fehon et al., 1997
The dendritic tree of the VS1 neuron
There are six vertical system cells in each Drosophila lobula plate that bear a close structural resemblance to the well characterized VS neurons in blowflies and house flies (Pierantoni, 1976
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Figure 1. Structure of the VS1 neuron. The position of a VS1 cell is shown in the context of the whole Drosophila brain by the MARCM labeling method (A). The dendrites can be seen in the lobula plate (arrows), and the axon extends medially (arrowhead), terminating near the midline. A close-up view of the dendrites of a VS1 cell (B) shows a major dendritic shaft that sweeps from dorsal to ventral. Smaller branches leave this shaft to form a dendritic field that covers that lateral portion of the lobula plate. A closer view of the dendrites of a different VS1 clone (C) shows small spine-like structures (arrows). Like vertebrate spines, these structures are rich in actin, as evidenced by dendrites with spines brightly stained against actin-GFP (arrows; D). Scale bars: A, 100 µm; B, 25 µm; C, D, 5 µm. D, Dorsal; V, ventral; M, medial; L, lateral. Wild-type flies in A-C are hs-flp/+; FRTG13, tubP-GAL80/FRTG13, UAS-mCD8-GFP; GAL4-3A/+ or hs-flp, UAS-mCD8-GFP/+; tubP-GAL80, FRT2A/GAL4-3A, FRT2A. Genotype for D is tubP-GAL80, hs-flp, FRT19A/yw, FRT19A; UAS-GFP-actin, UAS-myc-tubulin/+; GAL4-3A/+.
Because different neurons of the vertical system have different characteristic structures and levels of complexity (Scott et al., 2002
To define quantitatively some aspects of the structure of the dendrites, we first obtained three-dimensional confocal images of VS1 dendritic trees and then traced the dendrites to produce three-dimensional computer diagrams of the dendrites. From these tracings, we measured dendritic branching complexity on the basis of the total number of branch points found in the dendrites of single VS1 cells. We also used the tracings to determine the combined length of all of the dendritic branches for each cell (Table 1).
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Table 1. The effect of Cdc42 mutation on VS1 neurons Dendritic spines of the VS1 neuron
Of special interest in these VS neurons is the presence of structures that resemble dendritic spines found in many vertebrate neurons (Fig. 1C, arrows). In vertebrates, dendritic spines represent the locations of excitatory synapses (for review, see Bonhoeffer and Yuste, 2002
Another characteristic feature of vertebrate dendritic spines is that they are actin-based structures, whose changes in morphology may be important for synaptic plasticity (Bonhoeffer and Yuste, 2002
Together with the EM studies from larger insects summarized above, we propose that these spine-like structures in insect VS cells are similar to vertebrate dendritic spines and will refer to them as spines hereafter for simplicity. Future morphological and physiological studies are needed to determine how analogous these spines are to their vertebrate equivalent.
Cdc42 mutants affect dendritic caliber consistency, branching pattern, and dendritic spine density
Having characterized wild-type VS1 dendritic branching patterns and dendritic spines, we compared them with those in single-cell MARCM clones in which the labeled VS1 cells are homozygous for loss-of-function mutants of Cdc42. Most experiments reported here made use of the Cdc424 allele, which contains a mutation in a consensus splice acceptor that leads to strong loss-of-function (Fehon et al., 1997
VS1 neurons homozygous for Cdc424 show a variety of defects compared with wild type (Figs. 2A,B,D, 3A,B). Whereas the dendrites of wild-type VS cells taper smoothly from thick near the base to thin at distal tips (Fig. 1B), the caliber of Cdc424 VS cells is occasionally inconsistent (Table 1). Some dendrites are thinner near their major branches than in more distal positions (Fig. 2A, arrows). Also, the branching pattern of the dendrites is often abnormal. In wild-type VS1 cells, major branches off of the main dendritic shaft send their smaller dendrites only to the region near the original branch. A dendritic tip in the ventral part of the field, for instance, would be derived from a major branch off of the ventral part of the main shaft (Fig. 1B). In Cdc42 mutant cells, dendritic tips may be derived from major branches in distant parts of the field (Fig. 2A, arrowheads). One branch in particular, the most medial branch in the dendritic tree, is often shifted in Cdc424 cells (Table 1). In wild-type VS1 neurons, the initial branches extend almost directly dorsally, departing from the main branch near where it begins to turn ventrally (Scott et al., 2002
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Figure 2. Dendritic phenotypes in Cdc42 mutant neurons. VS1 cells homozygous for Cdc424 show defects in dendrite caliber, in which distal dendrites are thicker than proximal dendrites (A; arrows), and misguided dendrites, such as one that innervates the ventral region of the dendritic field despite its originating from a dorsal branch (A; arrowheads). Another Cdc42 mutant neuron shows a first branch that is shifted medially (B; arrow). For comparison with a normally positioned first branch, see Figure 1B, or A and C in this figure. Qualitative phenotypes are rescued in Cdc424 mutant cells with a UAS-Cdc42 transgene (C). A close-up view of a Cdc42 mutant VS1 dendrite (D) shows fewer spines (arrows) compared with wild type (Fig. 1C,D). Scale bars: A-C, 25 µm; D, 5 µm. D, Dorsal; V, ventral; M, medial; L, lateral. Cdc42 mutant flies are tubP-GAL80, hs-flp, FRT19A/yw, Cdc424, FRT19A; UAS-mCD8-GFP/+; GAL4-3A/+ for A, B, and D. Rescue flies are tubP-GAL80, hs-flp, FRT19A/yw, Cdc424, FRT19A; UAS-mCD8-GFP/+; GAL4-3A/UAS-Cdc42 in C.
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Figure 3. Axonal phenotypes in Cdc42 mutant neurons. The axonal terminus of a wild-type VS1 neuron is shown in A. The axon splits into two major branches, each of which may have one or a few additional small branches. All branches remain in the vicinity of the medially extending major branches. The axonal terminus of a Cdc424 VS1 neuron is shown in B. There is an increase in the number of branches, the termini of the axons are often tipped with enlarged structures (arrows), and axons occasionally turn laterally (arrowhead), away from the midline. Scale bars, 10 µm. D, Dorsal; V, ventral; M, medial; L, lateral.
Perhaps the most remarkable defect in Cdc42 mutant neurons is the reduction of the numbers of well developed dendritic spines (compare Fig. 2A,B with Fig. 1B). At high magnification (compare Fig. 2D with Fig. 1C,D), we did observe spines that are similar to wild type, but these spines are not as evenly spaced and the density is much reduced. Using a uniform definition of regarding protrusions between 1 and 3 µm as spines (see Materials and Methods), we recorded a 50% reduction in Cdc42 mutant VS1 cells compared with wild-type control (Table 1).
Axon defects in Cdc42 mutants
Wild-type VS1 axons project medially, with stereotyped branching pattern and terminal fields (Figs. 1A, 3A). This pattern is disrupted in Cdc424 VS1 cells, some of which exhibit misguided axons that turn laterally, away from their wild-type target field (Fig. 3B, arrowhead). Additionally, the axons of Cdc424 neurons form more branches in this terminal field than do their wild-type counterparts (Table 1) and often exhibit enlarged terminals rarely observed in wild type (Fig. 3B, arrows).
Attempts to assess cell autonomy of Cdc42 action
In the MARCM strategy, all labeled clones are homozygous mutant; however, some homozygous mutant cells may not be labeled because they do not express the GAL4 line used to visualize the clone. Because the expression of the GAL4-3A driver is primarily restricted to the lobula plate giant neurons, it remains possible that some phenotypes we observe in Cdc424 MARCM clones are attributable to disruption of Cdc42 function in as yet uncharacterized neurons presynaptic or postsynaptic to VS1, or glia. To determine the degree to which the phenotype is cell autonomous, we expressed UAS-Cdc42 transgenes in Cdc424 MARCM clones, such that wild-type Cdc42 is resupplied only to the labeled neurons. An important caveat to this experiment is that the transgene is not immediately expressed after generation of the clone. The GAL80 repressor protein must be sufficiently diluted, which can take a long time in single-cell clones, to allow GAL4-induced gene expression. For instance, we could not observe reliable marker expression in VS1 until very late pupa, well after the initial dendritic morphogenesis has already taken place (data not shown). Indeed, many of the quantitative defects in Cdc424 cells are not affected by the UAS-Cdc42 transgene (Table 1). Nevertheless, certain qualitative defects, such as dendritic caliber or branching pattern, appear to be rescued by the expression of the wild-type Cdc42 transgene (Fig. 2C, Table 1), indicating that Cdc42 function in at least these aspects of dendritic morphogenesis is cell autonomous. The failure to rescue dendritic length or spine density defects could be caused, strictly speaking, by the non-autonomous effect of Cdc42. More likely, it is a result of inadequate expression at a time when Cdc42 is required, implying that controlling dendritic length (likely a consequence of dendritic branch misguidance) and spine formation may require a higher amount of Cdc42 than controlling initial branch formation and caliber consistency.
Discussion
Previous studies using dominant-negative and constitutively active Cdc42 mutants have implicated Cdc42 in a variety of functions relating to dendritic growth, branching, and branch stability (Luo et al., 1994
Compared with mutants defective in Rac GTPases (Ng et al., 2002
Despite having grossly normal dendritic trees, Cdc42 mutant VS1 cells do display a number of important defects in dendritic morphogenesis. First, dendritic caliber consistency is disrupted. A universal property of dendritic trees is that they taper smoothly from thick near the base to thin at distal tips. To our knowledge, this is the first mutant that has been described to disrupt this property, suggesting that Cdc42 activity is necessary for regulating dendritic caliber diameter, an aspect that may be important for integration of synaptic potential within the dendrites (Jan and Jan, 2001
Second, although the gross dendritic branching complexity is not affected, the stereotyped branching pattern is disrupted (Table 1). This defect may reflect abnormal responses of the dendrites to branching signals at key locations during development, consistent with the idea that Cdc42 transduces extracellular signals to regulate dendritic branching rather than being required for the cell biology of branching per se.
Third, Cdc42 mutation has a drastic effect on dendritic spine development: it reduces dendritic spine number to approximately one-half of that of wild type. It remains possible that the reduction in number is in fact reduction in size, such that the smaller-sized "spines" are no longer quantified as spines by our criterion. Given the small size of even the wild-type dendritic spines approaching the resolution limit of light microscopy, it is currently difficult to distinguish these possibilities. Whatever the mechanism is, our observation underscores the importance of endogenous Cdc42 in spine development. Previous studies in mammalian neurons using dominant mutant expression have implicated the function of Rac and Rho in spine development (Luo et al., 1996
In summary, our data demonstrate a genetic requirement for Cdc42 in certain aspects of VS1 dendrite development, including regulating dendritic branching, guidance, caliber consistency, and dendritic spine density. Given the function of Cdc42 in regulating actin polymerization (Etienne-Manneville and Hall, 2002
FOOTNOTES Received Aug. 15, 2002; revised Jan. 23, 2003; accepted Jan. 29, 2003.
This work was supported by National Institutes of Health Grants R01-NS36623 (L.L.) and TR32-HD07249 (E.K.S.). We thank R. Fehon for providing Cdc42 mutants and G. Jefferis and A. Goldstein for their comments on this manuscript.
Correspondence should be addressed to Liqun Luo at the above address. E-mail: lluo{at}stanford.edu.
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