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Vol. 10, Issue 1, 225-243, January 1999
and
*Abteilung Biophysik and
Abteilung Molekulare
Zellforschung, Max-Planck-Institut für Medizinische Forschung,
D-69120 Heidelberg, Germany; and
Department of Cell
Biology, Duke University Medical Center, Durham, North Carolina 27710
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ABSTRACT |
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 Top
 Abstract
 Introduction
Materials and methods
Results
Discussion
References
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The identification and functional characterization of Dictyostelium discoideum dynamin A, a protein composed of 853 amino acids that shares up to 44% sequence identity with other dynamin-related proteins, is described. Dynamin A is present during all stages of D. discoideum development and is found predominantly in the cytosolic fraction and in association with endosomal and postlysosomal vacuoles. Overexpression of the protein has no adverse effect on the cells, whereas depletion of dynamin A by gene-targeting techniques leads to multiple and complex phenotypic changes. Cells lacking a functional copy of dymA show alterations of mitochondrial, nuclear, and endosomal morphology and a defect in fluid-phase uptake. They also become multinucleated due to a failure to complete normal cytokinesis. These pleiotropic effects of dynamin A depletion can be rescued by complementation with the cloned gene. Morphological studies using cells producing green fluorescent protein-dynamin A revealed that dynamin A associates with punctate cytoplasmic vesicles. Double labeling with vacuolin, a marker of a postlysosomal compartment in D. discoideum, showed an almost complete colocalization of vacuolin and dynamin A. Our results suggest that that dynamin A is likely to function in membrane trafficking processes along the endo-lysosomal pathway of D. discoideum but not at the plasma membrane.
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INTRODUCTION |
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Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
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Dynamins form a protein family within the GTP-binding protein
superfamily whose members share considerable sequence identity in the
amino-terminal half of the molecule, particularly in the region around
the tripartite GTP-binding motif. Large variations in size and sequence
are observed in the carboxy-terminal half and are thought to reflect
functional differences. Accordingly, members of the dynamin family have
been implicated in a wide range of cellular processes, including
meiotic spindle pole separation (Yeh et al., 1991
),
mitochondrial genome maintenance (Jones and Fangman, 1992), cell plate
formation in plants (Gu and Verma, 1996), protein trafficking,
biogenesis of thylakoid membranes (Park et al., 1998), and
various forms of endocytosis. The best characterized function of a
dynamin family member, that in clathrin-mediated endocytosis, was
deduced from observations in Drosophila and mammalian cells.
Initial studies of D. melanogaster shibire mutants (Kosaka and Ikeda, 1983a,b) and later mammalian cells expressing mutant forms
of dynamin (Damke et al., 1994) showed an increase in the presence of invaginations at the plasma membrane. Dynamin-1 localizes to endocytic clathrin-coated pits and self-assembles into rings at the
neck of clathrin-coated buds. This process is thought to be a
key step in the mechanism by which vesicles are `pinched off' at the plasma membrane as the dynamin rings constrict
(Hinshaw and Schmid, 1995; Takei et al., 1995).
Many questions remain about the structure and function of dynamins,
particularly in regard to a potential role in the organization of the
cytoskeleton and the regulation and maintenance of cell shape (Urrutia
et al., 1997). The present study attempted to identify a
dynamin homologue in Dictyostelium discoideum and to
elucidate its function in this genetically tractable, unicellular
organism. These highly motile cells have proven to be a useful system
in which to investigate the molecular mechanisms regulating protein and
vesicular trafficking along the biosynthetic and endosomal pathways.
There is good evidence that many of the components involved in
secretion, protein sorting, and endocytosis are well conserved between
D. discoideum and mammalian cells (Buczynski et
al., 1997).
We report here the identification, cloning, and characterization of the
dynamin-like protein dynamin A from D. discoideum. A
PCR-based approach was used to identify dymA, the gene
encoding dynamin A. The functional importance of dynamin A was examined by gene replacement and overexpression of the cloned gene in D. discoideum. Disruption of dymA causes major changes in
the morphology and behavior of D. discoideum cells. The
mutant cells are large and multinucleated and grow more slowly than
wild-type cells. Cells lacking a functional copy of dymA
show a marked reduction in cell polarity, display aberrant motile
behavior, and frequently fail to complete cytokinesis. A role of
dynamin A in endocytosis is suggested by the observations that,
compared with control cells, the uptake of fluid-phase markers is
twofold reduced in dymA
cells and the transit
time of the fluid-phase markers is twofold increased. Analysis by
electron microscopy revealed extensive areas with small vesicular
profiles in dymA cells and changes in the
morphology of mitochondria and the cell nucleus. A causal relationship
between the lack of dynamin A and these phenotypic changes was
confirmed by complementation of the dymA cells
with the cloned gene. Recovery of dymA expression was
accompanied by stable reversion to the wild-type phenotype.
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MATERIALS AND METHODS |
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Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
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Strains, Media, and Buffers
D. discoideum wild-type and mutant strains were grown
on plastic culture dishes or in conical flasks in HL-5c medium. Media for growth of dymA strains HDM1701, HDM1702,
and HDM1703 contained 4 µg/ml blasticidin (ICN Biomedicals, Eschwege,
Germany). Buffers used were TBS (20 mM Tris-HCl, 150 mM NaCl, pH 7.5)
and PBS (10 mM Na2HPO4, 2 mM KH2PO4, 137 mM NaCl, pH 7.5). Escherichia
coli strain XL1-Blue (Stratagene, Heidelberg, Germany) was used
for all DNA work unless stated otherwise.
Cloning and Sequencing
The D. discoideum dymA gene was cloned using PCR
techniques. The oligonucleotide pair used to amplify the
dynamin-related sequences, 5'-GATTTCTTACCAGGAGGTTCAGGTAT-3' and
5'-GCATCIGTACCTTCATCCAT-3', corresponds to the conserved amino acid
sequences DFLPRGSGI and MDEGTDA of human dynamin-1. For the isolation
of the cDNA clone, a D. discoideum 
-gt11 cDNA library
(Clontech, Heidelberg, Germany) was divided into ten fractions made
from plates with ~50,000-100,000 plaques. Each fraction was screened
using PCR for the appearance of a 0.5-kilobase (kb) fragment. One of
the positive fractions was subdivided into eight fractions made from
plates with ~15,000 plaques and rescreened. The final cDNA clone
was isolated by filter screening of a positive fraction using the
500-base pair (bp) PCR fragment as the probe. Standard cloning and DNA
hybridization methods were used (Sambrook et al., 1989). A
genomic clone was isolated to obtain the entire coding sequence of
dymA. D. discoideum genomic DNA was purified from
Ax2 cells as described by Manstein et al., 1989.
Southern blot analysis revealed that a 6- to 7-kb HindIII-EcoRI fragment harbored the complete
DymA gene. Consequently a 6- to 7-kb
HindIII-EcoRI partial genomic DNA library was
created in pBluescript using E. coli strain XL2-Blue
(Stratagene) as the host, and 1500 colonies were screened with the
500-bp PCR fragment described above. Sequencing confirmed that a 6.6- kb HindIII-EcoRI fragment contained the entire
dymA gene, and the genomic clone was designated pBS-DYMA.
Sequencing was performed using a Sequenase kit (Amersham Buchler,
Braunschweig, Germany). Restriction enzymes and T4 DNA ligase were from
Boehringer Mannheim (Mannheim, Germany).
Gene Replacement
Plasmid pBS-
DYMA was generated for the replacement of the
dymA gene in D. discoideum (Figure 3). First,
pBS-DYMA was cut with SpeI and religated to obtain
pBS-DYMASpe. The 134-bp BamHI-EcoRV DNA
fragment of pBS-DYMASpe was then replaced by the 1.4-kb blasticidin S resistance cassette from pBsr2 (Sutoh, 1993). The resulting construct (pBS-DYMA) had the blasticidin S resistance cassette inserted 664 bp downstream of the dymA start codon and in
the same orientation as the dymA gene.
For transformation of wild-type Ax2 cells, 20 µg of pBS-DYMA were
digested with NdeI-SpeI to release the
replacement fragment from the vector sequence. The DNA was
dephosphorylated with shrimp alkaline phosphatase (Amersham Buchler),
phenol/chloroform extracted, ethanol precipitated, and resuspended in
20 µl Tris-EDTA, pH 8.0. Alternatively, after digestion with
NdeI-SpeI the replacement fragment was gel
purified and resuspended in 20 µl Tris-EDTA, pH 8.0. Transformation
of D. discoideum cells was carried out as described (De
Hostos et al., 1991). Selection for transformants was
applied 24 h after transformation in medium containing 4 µg/ml blasticidin S. Colonies appeared around day 5. Transformants were picked after 7-10 d and subcloned by spreading series of diluted cell
suspensions onto SM agar plates containing Klebsiella
aerogenes. Transformants were screened by PCR, and the
replacement event was verified by Southern blot analysis.
Extrachromosomal Expression of Dynamin A
For complementation studies, the entire dymA gene was
recovered from plasmid pBS-DYMA as a 6.6-kbp
SalI-XbaI fragment. This fragment also contained
1.5 kbp of 5'-flanking region including the native promoter of
dymA. The SalI-XbaI fragment was
cloned into the Dictyostelium expression plasmid pDXA-3C
(Manstein et al., 1995), cut
SalI-XbaI thus releasing the actin 15 promoter. The resulting construct (pDX-DYMA) was transformed into
dymA cells, and transformants were selected in
growth medium containing 10 µg/ml G418.
Expression of Green Fluorescent Protein (GFP)-Dynamin A
A vector for expression of a GFP-dynamin A fusion protein in
D. discoideum under the control of the actin 15 promoter was constructed from the transformation vector pDEX H (Faix et
al., 1992). The insert contained a continuous reading frame
composed of, first, the coding sequence of S65T-GFP from A. victoria (Heim et al., 1995); second, an
oligopeptide linker consisting of four glycine-serine-glycine repeats
(Westphal et al., 1997); and third, the entire
dymA coding sequence. The vector was introduced into the
genome of Ax2 cells using electroporation, and transformants were
selected in growth medium containing 10 µg/ml G418. The transformant clone HDM1718 was used for morphological studies.
Antibody Production and Western Blot Analysis
A fragment containing amino acids 1-380 was expressed as GST fusion protein and purified on a GST-agarose column. Polyclonal antisera against dynamin A were obtained from rabbits immunized with the GST-fusion protein. Antibodies were affinity purified using a dynamin fragment corresponding to amino acids 1-568 that was CNBr coupled to Sepharose. Eluted antibody was precipitated with 50% NH4SO4, resuspended in PBS, and dialyzed overnight at 4°C against PBS. For immunoblotting, D. discoideum proteins from wild-type and mutant strains were separated on a 10% SDS-PAGE gel and electroblotted onto nitrocellulose (Schleicher & Schüll, Dassel, Germany). The nitrocellulose blot was blocked in TBS containing 5% nonfat dry milk powder for 1 h, incubated with 1:1000 dilution of affinity-purified anti-dynamin antibody in the same buffer for either 1 h at room temperature or overnight at 4°C followed by detection with an HRP-conjugated secondary antibody (Bio-Rad, Munich, Germany). Detection by ECL was performed according to manufacturer's instructions (Amersham Buchler).
Fluorescence Microscopy
Cells at a density of 1 × 106 cells/ml were
placed on 12-mm coverslips and allowed to attach for 30 min. Fixation
of cells was performed in methanol applying a temperature gradient from 
85 to 35°C for 30 min (Neuhaus et al., 1998). The
cells were rehydrated in PBS and blocked in PBS containing 3% BSA
followed by incubation in primary antibody for 30 min at room
temperature. Immunolocalization of dynamin A used antibody PAD1 at a
dilution of 1:20 in PBS containing 3% BSA and 0.1% Triton X-100. For
immunostaining of mitochondria, the monoclonal 
-mitoporin-antibody
70-100-1 was used (Troll et al., 1992). Other primary
antibodies used were monoclonal antibody 190-340-8 (Weiner et
al., 1993) to stain the Golgi complex, monoclonal vacuolin
antibody 221-1-1 to stain late endosomes (Rauchenberger et
al., 1997), and a polyclonal GFP antibody (Clontech). Primary
antibodies were diluted 1:5 before use or 1:200 in the case of the
polyclonal GFP antibody. After washing with PBS and PBS/3% BSA, cells
were incubated for 20 min in Cy3-labeled secondary antibody (Amersham
Buchler) diluted 1:500. Nuclei were stained with 0.1 µg/ml
4',6'-diamidino-2-phenylindole (DAPI) for 5 min. Coverslips were
mounted on glass slides with Moviol (Heimer and Taylor, 1974). Double
immunofluorescence was performed using Cy3-labeled secondary antibodies
together with Alexa488-labeled secondary antibodies (Molecular Probes,
Leiden, Germany). Images were recorded on a Zeiss Axiovert 135 inverted
microscope equipped with a Quantix camera (Photometrics, Tucson, AZ),
controlled by IP-Lab software. For confocal microscopy, a confocal
microscope DM/IRB (Leica, Nussloch, Germany) was used, and
optical sections were recorded at 0.4 µm per vertical step and 8 times averaging.
Video Microscopy
For video microscopy, cells were transferred to covered chamber glasses (Nunc, Naperville, IN). Sequences were recorded in real time on videotape using a Sony SSC-370CE video camera with an Argus 20 controller (Hamamatsu Photonics, Herrsching, Germany). Time lapse series were acquired using the Photometrics Quantix camera and transferred to a Macintosh 9500 for analysis and storage.
Synchronous morphological differentiation was induced by starvation on MMC agar (20 mM 2-(N-morpholino)ethanesulfonic acid [MES], pH 6.8; 2 mM MgCl2; 0.2 mM CaCl2; 2% [wt/vol] Bacto agar [Difco, Detroit, MI]). Structures from various stages of development were visualized using an Olympus B061 microscope (Olympus, Lake Success, NY) and the Sony video camera. A Scion VG-5 frame grabber was used for transfer of images to a Macintosh 9500.
Transmission Electron Microscopy (TEM)
TEM for Figure 9 was performed as described by Novak and
co-workers (1995). TEM for Figures 10 and 12 was carried out according to Neuhaus et al. (1998).
Measurement of Pinocytosis and Phagocytosis
Fluid-phase endocytosis and exocytosis of surface-attached
wild-type Ax2, rescue cells, and dymA cells
were quantitatively analyzed using a method adapted from Bacon et
al. (1994). Cells were grown to confluency on 6-cm Petri dishes or
in shaking culture at a density of 4 × 106 cells/ml.
To determine fluid-phase uptake, cells were incubated with 1 mg/ml
FITC-dextran in growth medium for various lengths of time. For
measuring exocytosis, surface-attached cells were incubated with 1 mg/ml FITC-dextran for 2 h, washed twice, and transferred to fresh
growth medium. To determine intracellular transit time of fluid phase,
cells were incubated with 5 mg/ml FITC-dextran for 10 min, washed
twice, and transferred to fresh medium. At the indicated times, cells
were washed twice with 200 mM phosphate buffer, pH 6.3, and once with
50 mM phosphate buffer, pH 9.2. Cells were resuspended in 1 ml 50 mM
phosphate buffer, pH 9.2, transferred to tubes, and lysed with 0.4%
Triton X-100. After centrifugation the fluorescence of the supernatant
was measured in an SLM 8000 spectrofluorimeter at excitation and
emission wavelengths of 493 and 516 nm, respectively. The data shown
were normalized with respect to total protein content of the cells, as
determined with Bradford reagent (Bio-Rad).
Phagocytic ability was measured by a modification to the method of
Temesvari and co-workers (1996). Briefly, 1-µm carboxylate-modified, fluorescent polystyrene beads (Molecular Probes) were incubated with
cells grown in shaking suspension culture to 3 × 106/ml. The ratio of cells to beads was 1:100. Samples (1 ml) were mixed with 4 ml ice-cold MES buffer, pH 6.5, and placed on a
8-ml cushion of 20% PEG 8000 in MES buffer. Centrifugation at
2000 × g for 10 min separated ingested beads from
uningested and attached beads. The uppermost layer and the cushion were
removed by careful aspiration, and the cell pellet was washed in 5 mM
glycine, 100 mM sucrose, pH 8.5. Cells were lysed in 100 µl of the
same buffer containing 1% octylglucopyranosid. Samples were diluted to
1 ml, and fluorescence intensities were measured using excitation and emission wavelengths of 595 and 644 nm, respectively. Normalization of
data to total protein content was as described above.
Functional Analysis of the Contractile Vacuolar System
To assess the function of the contractile vacuolar system the
method described by Kuwayama and colleagues (1996) was used. Amebae
were harvested by centrifugation, washed free of medium, and starved
for 1 h in phosphate buffer. Cells were incubated in the presence
of 300 mM glucose, water, or phosphate buffer as different osmotic
environments in plastic tissue culture dishes. Cells were then
monitored visually by video microscopy as described above. For
quantitative analysis of viability after treatment a certain amount of
cells were plated on bacteria lawns and the number of colonies counted
after 4 d.
Functional Analysis of the Mitochondrial System
To assess the function of the mitochondrial system, the activity
of the mitochondrial marker succinate dehydrogenase was measured in
whole-cell lysates as described by Morré and co-workers (1987). As a control, the activity of the cytoplasmic marker alkaline phosphatase was determined. Cells were washed in MES buffer,
resuspended at 3 × 107 cells/ml, and lysed by forced
passage through a 5-µm pore filter (Schleicher & Schüll). To
measure succinate dehydrogenase activity, 10-50 µl of whole-cell
lysate were mixed with a buffer containing 40 mM sodium phosphate (pH
7.4), 250 µg/ml tetranitroblue tetrazoliumchloride (Sigma), 10 mM
sodium succinate to a final volume of 500 µl and incubated at room
temperature. After 30-60 min the reaction was stopped by the addition
of 500 µl 4% SDS, and absorbance was measured at 570 nm.
Alkaline phosphatase activity was measured by mixing 10-50 µl of whole cell lysate with a solution consisting of 50 mM Tris-HCl (pH 9.0), 10 mM MgCl2, and 2.6 mg/ml p-nitrophenyl phosphatase (Sigma) to a final volume of 1 ml. After incubation for 30 min at room temperature, absorbance was measured at 404 nm. The data obtained in the succinate dehydrogenase assay were normalized for protein content or alkaline phosphatase activity.
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RESULTS |
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Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
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We used PCR techniques to identify dymA, the gene encoding dynamin A. Both cDNA and gDNA libraries were screened to obtain a full-length dymA clone. Comparison of cDNA and gDNA revealed a single 83-bp intron near the 5'- end of the gene.
The nucleotide sequence of dymA revealed an open reading
frame of 2559 bp encoding the 853-amino acid polypeptide chain of dynamin A (Figure 1A). With a calculated
molecular mass of 96.1 kDa, dynamin A is similar in size to other
members of the dynamin family (Obar et al., 1990, van der
Bliek and Meyerowitz, 1991, Guan et al., 1993). Dynamin A
contains the dynamin consensus motif LPRGSGIVTR (residues 51-60) and
sequences corresponding to the tripartite GTP-binding motif (Bourne
et al., 1991). The high homology of dynamin A to other
members of the dynamin family is mainly confined to the N terminus. For
the first 360 amino acids the sequence identity is 57% to rat DLP1,
56% to human dynamin-1, 54% to D. melanogaster shibire
protein, and 55% to yeast Dnm1p (Figure 1B). The GGARI motif (residues
360-364) marks the carboxy-terminal end of the region of high
similarity between dynamin A and the shibire-like dynamins. As
previously described for all dynamin-like GTPases, the C terminus shows
a higher level of sequence divergence. In the central part of dynamin A
(residues 365-500), the highest degree of sequence similarity is
observed with DLP1 (49%), Dnm1p (43.0%), and Vps1p (38.3%).
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The region of dynamin A formed by residues 500-730 shows no similarity to the primary sequence of other members of the dynamin family. Secondary structure analysis shows that this region is highly hydrophilic and has a high surface probability. This part of dynamin A is almost devoid of charged residues, but is rich in polar amino acids (67%) and contains a high proportion of glutamine (25%), asparagine (23%), and serine (14%) residues that appear in long stretches of up to 13 amino acids (Figure 1A). The central part of the QNS-rich region, corresponding to residues 573-624, comes closest to the proline-rich domain observed with other dynamin family members. This region is basic in composition (pI = 10.0), and 12 of 51 residues are prolines.
The C-terminal domain of dynamin A (residues 730-853) shares 51 and
43% sequence identity with the corresponding regions of DPL1 and
Dnm1p. This part of the protein is predicted to be -helical and
marked by an abundance of charged residues (40%), with the number of
basic residues (20) almost equaling the number of acidic residues (22).
The C-terminal end of classical dynamins is formed by a basic, proline-
and arginine-rich domain (PRD) that exhibits no significant sequence
similarity to that of dynamin A. However, residues 660-742 of
dynamin-1 share 43% sequence identity with residues 730-853 of
dynamin A (Figure 1C). This 13-kDa domain of dynamin-1 corresponds to a
GTPase effector domain (GED) and is required for efficient GTPase
activity (Muhlberg et al., 1997).
After lysis of wild-type cells and cells overproducing the protein,
dynamin A was predominantly (~90%) found in the soluble fraction
(Figure 2). Further subcellular
fractionation of the membrane-associated protein by sucrose gradient
centrifugation showed the protein to be enriched in the microsomal
fraction (data not shown). The polyclonal antibody PAD1, specific for
the N-terminal 380 amino acids of dynamin A, was used for
immunoblot analysis. This antibody reacts predominantly
with a 96-kDa antigen in whole-cell lysates of Ax2 (see below). The
size of the detected antigen agrees well with that of the purified
protein (Wienke et al., 1997) and the molecular mass of
dynamin A deduced from its amino acid sequence.
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Generation of dymA Cells by Gene Replacement
The dymA locus was disrupted by transforming wild-type
Ax2 cells with linearized replacement fragments from vector
pBS-DYMA, using resistance against blasticidin S as a selectable
marker. After 5-8 d of selection, typically 100-150 colonies were
obtained. Thirty to 40 transformants were cloned and screened for the
disruption of the dymA gene by PCR (data not shown). In
three independent experiments, screening indicated that 5-15% of the
transformants were potentially dymA. The
frequency of the desired recombination event was higher (30-40%) when
the replacement fragment was gel purified before transformation.
Positive transformants from the PCR screen were analyzed by Southern
blotting to confirm the disruption of the dymA gene locus and to determine its molecular organization in the mutant strains. A
0.6-kb fragment from the 5'-end of the dymA cDNA was used as a probe. The expected hybridization pattern for this probe with wild-type DNA is depicted in Figure 3A.
Homologous recombination with the replacement construct is expected to
cause a band shift for the XbaI-EcoRI digest
from 7.5 to 3.3 kb and for the ClaI digest from 2.6 to 3.8 kb in the dymA cells (Figure 3B). The Southern
blot in Figure 3C is consistent with the predicted change in the
hybridization pattern. Further Southern blot analysis with the
blasticidin resistance cassette as a probe confirmed that only one copy
of the replacement fragment had been integrated in the dymA
gene and no other gene loci had been affected (data not shown). Cell
lines HDM1701, HDM1702, and HDM1703, each with a disrupted
dymA gene locus, were obtained from three different
transformations and will be referred to, in the following text, as
dymA cells.
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As expected from the disruption of the dymA gene locus, the
96-kDa antigen was not detectable in whole-cell lysates of
dymA cells by immunoblot analysis
(Figure 4, lane 2).
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Complementation of the dymA Cells
To confirm that phenotypic changes in the
dymA cells are explicitly attributable to the
loss of the dymA gene product, the mutant strain was rescued
by reintroduction of functional copies of dymA. The
multicopy plasmid pDX-DYMA, harboring the entire dymA gene
under the control of its native promoter, was used to transform
dymA cells. Complementation of
dymA cells led to the production of the 96-kDa
antigen at levels 10- to 50-fold higher than those observed for Ax2
cells (Figure 4, lane 3) and rescued all phenotypic changes observed
with dynamin A-depleted cells.
Growth and Appearance of dymACells
The dymA gene product is not essential for D. discoideum growth. However, dymA cells
grow under all conditions tested approximately twofold slower than the
parental Ax2 cells. In axenic media, Ax2 cells grow with doubling times
<12 h. Exponentially growing cultures of dymA
cells double every 24 h under the same conditions. In suspension culture, Ax2 cells reach cell densities of 1 × 107
cells/ml and above while dymA cells grow to a
maximum cell density of 2 × 106 cells/ml.
Unusually large cells and the frequent occurrence of cytoplasmic
bridges connecting neighboring cells are prominent features of
populations of surface-attached dymA cells
(Figure 5A). Staining with DAPI showed
that most dymA cells are multinucleated with
40% of the cells containing three or more nuclei and some upwards of
20 nuclei. This is in comparison to wild-type cells where 98% of the
cells have one or two nuclei with <2% having three or more nuclei.
The frequent occurrence of large multinucleated cells and cytoplasmic
bridges is reminiscent of myosin II-defective cells, which are unable
to carry out normal cytokinesis and whose ability to divide requires
attachment to a surface (De Lozanne and Spudich, 1987; Neujahr et
al., 1997).
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However, unlike myosin II-depleted cells, dymA
cells are able to grow in suspension culture. When
dymA cells are transferred from shaken culture
to Petri dishes, the multinucleated cells start within minutes to
undergo amitotic cell divisions by tearing themselves into smaller
fragments by traction-mediated cytoplasmic fission (Figure 5A).
Amitotic cell divisions are also observed at an increased frequency
shortly after the transfer of dymA cells to
nutrient-free salt solutions. However, when cells are grown axenically
or in association with bacteria, cytokinesis is in most instances
(<95%) synchronized with mitosis. We used time-lapse video microscopy
to follow cytokinesis in surface-attached and synchronized
dymA and Ax2 cells. The timing and the
sequence of shape changes during cytokinesis were similar for both
strains. Approximately 2-3 min were required to pass through cleavage
furrow constriction until only a thin filamentous connection persisted
(Figure 5B). This connection is very short lived in wild-type cells. In
all recorded events the connection broke within 2 min and reached a
maximal length of 20 µm. In contrast, long cytoplasmic bridges are a
distinct phenotypic feature of surface-attached
dymA cells (Figure 5C). They persist for
several minutes to several hours and reach up to 300 µm in length.
The incipient daughter cells can undergo additional rounds of
cytokinesis without disruption of the cytoplasmic bridges, leading to
networks of interconnected cells. As long as the cytoplasmic bridges
persist, the almost completely separated daughter cells can fuse again,
thus giving rise to large multinucleated cells. A similar defect in
cytokinesis was previously reported for calmodulin-depleted D. discoideum cells (Liu et al., 1992).
The average dymA cell appears
to lack polarity but is highly dynamic (Figure
6). Cells were frequently observed to
cyclically extend and retract lamellopodia around the entire cell
periphery. Pseudopodial extensions and long filopodia were also
commonly observed; however, their distribution on the cell surface
appears random. When we measured the speed of cells undergoing random walks on a glass surface, we found that dymA
cells are very motile and move at rates similar or greater than those
observed for wild-type cells. Cell movement was measured under two
different nutrient conditions. First, in axenic medium, dymA cells moved at a rate of 4.4 µm/min
(SD ± 2.7; n = 98) and Ax2 cells at 4.7 µm/min (SD ± 2.9; n = 86). Second, movement was tested after transfer to a
buffered salt solution. The motility of D. discoideum cells
varies with the developmental stage and reaches a maximum at the onset
of aggregation about 8 h after transfer to starvation conditions
(Varnum et al., 1985). Thus, transfer to starvation
conditions induced an increase in the velocity of Ax2 cells to 5.8 µm/min (SD ± 3.2; n = 74) compared with vegetative cells.
The maximum velocity of dymA cells was 6.8 µm/min (SD ± 3.2; n = 74) during early development. Simultaneously, the multinucleated dymA cells
undergo several rounds of traction-mediated cytoplasmic fission, which
inhibits the directed movement of the cells. The chemotactic response
of dymAcells was normal (data not shown).
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Development
The developmental program of D. discoideum is initiated
upon starvation. Cells start emitting cAMP pulses and aggregate into mounds consisting of ~105 cells. These mounds undergo a
series of morphological changes that culminate in the formation of a
fruiting body (Raper, 1935). The transcriptional regulation of
dymA expression during development was assessed by probing
Northern blots of RNA isolated at a series of developmental stages. A
~3-kb dymA transcript was detected in vegetative cells
and, at similar levels, at all later developmental stages (data not shown).
When dymA cells were placed in starvation
conditions on nonnutrient agar plates, the cells took 10 h to
start streaming in comparison to 7 h observed for wild-type cells.
Except for this difference in timing, early development of
dymA cells appeared similar to that of the
wild-type cells. The delay in the onset of streaming of
dymA cells may, in part, be explained by the
requirement to undergo several rounds of cytokinesis by traction
mediated cytofission before efficient development can be initiated.
Development of dymA cells is completed by
30-36 h, while Ax2 cells completed development within 24-26 h. The
final developmental morphology of dymA cells
results in shorter fruiting bodies consisting of a tapered stalk with
enlarged basal disk and spore mass at the apical tip and a
second cluster of spores laterally attached to the center of the stalk
(Figure 7B). Only 10-20% of the spores
formed by dymA cells were resistant to heat
treatment and germinated after incubation at 42°C for 30 min, in
contrast to ~90% for wild-type cells (data not shown).
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When D. discoideum cells are plated at low density in
association with bacteria on nutrient agar plates, the bacteria form a
confluent lawn and the D. discoideum cells form clonal
plaques within the lawn as the bacteria are digested. Consistent with their reduced rate of growth under axenic conditions, the rate at which
dymA cells advanced on a bacterial lawn was
approximately twofold slower than that of wild-type cells. In areas
behind the advancing edge, where the dymA
cells had depleted the bacteria, the cells starved and gave rise to
fruiting bodies that resembled those observed on nonnutrient agar plates.
Endocytosis and Osmoregulation in dymA Cells
The role of dynamin A in the endosomal-lysosomal system of
D. discoideum was tested by measuring the uptake of the
fluid phase marker fluorescein-labeled dextran. In comparison to cells
containing a functional copy of dymA, the extent to which
the marker was accumulated was approximately twofold reduced in
dymA cells (Figure
8A). The initial rate of uptake for the
first 40 min was 33% slower for dymA than the
parental wild-type or rescue cells. Thus, the lack of a dynamin A has a
clear inhibitory effect on the initial rate of internalization and the
long-term accumulation of the fluid phase marker. Similar results were
obtained for cells grown on a substratum or in suspension.
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The release of fluid phase marker over time was measured to show that
the reduced rate of FITC-dextran uptake by the
dymA cells can be attributed to a deficiency
in internalization and not recycling to the media by a faster rate of
exocytosis. Cells were loaded for 2 h with FITC-dextran, washed
free of the marker, and resuspended in fresh medium. The amount of
fluid-phase marker that remained in the cells over time was measured.
Similar rates of exocytosis were determined for
dymA cells and cells producing dynamin A
(Figure 8B).
Examination of intracellular transit time by exposing the cells to a
10-min pulse of FITC-dextran revealed that the retention of the marker
is more than twofold prolonged in dymA
compared with wild-type and rescue cells. The half-life for
internalized FITC-dextran was 60 min in control cells and 150 min in
dymA cells (Figure 8C).
Phagocytosis is an inducible actin-dependent process. It is initiated
by adhesion of a particle to any region on the surface of a D. discoideum cell. To investigate whether dynamin A plays a role in
phagocytosis, dymA and control cells were
incubated with fluorescent polystyrene beads of 1 µm diameter for
various lengths of time. In contrast to the pinocytosis assays,
particle uptake experiments were performed with cells grown in shaking
suspension culture. Compared with Ax2 and rescue cells, the
dymA mutants exhibited a 50% increase of
total particle uptake (Figure 8D).
The best characterized function of dynamin-1 is its role in
receptor-mediated endocytosis via clathrin-coated pits (Herskovits et al., 1993; van der Bliek et al., 1993; Takei
et al., 1995). Therefore, we were particularly interested in
comparing the phenotype of dymA cells and
clathrin heavy chain-deficient D. discoideum cells (CHC cells). Coated vesicles are particularly enriched
near the microtubule-organizing center (MTOC) of wild-type cells and
were found to be completely absent in CHC cells
(O'Halloran and Anderson, 1992). In dymA
cells, coated vesicles were observed throughout the cytoplasm and in
large numbers (>20) near the MTOC. Coated pits were frequently observed in association with larger vesicles but not at the plasma membrane. One of the most prominent defects of CHC cells
is the absence of large vacuoles that form part of the contractile
vacuole system (Ruscetti et al., 1994). Examination of the
morphology and function of this osmoregulatory organelle in
dymA cells showed the contractile vacuole
system to function normally. Observation of
dymA cells by phase microscopy revealed the
cyclic filling and emptying of large vacuoles. Exposure to hypo- and
hyperosmotic conditions had no adverse effect on the viability of
dymA cells. Localization of two contractile
vacuole markers, calmodulin and the 100-kDa subunit of the
V-H+-ATPase (Fok et al., 1993; Zhu et
al., 1993), by immunofluorescence revealed no difference in the
appearance and organization of the contractile vacuole system of
dymA cells and that of the parental cell line
(data not shown).
Disruption of dymA Affects Organelle Morphology
The clear differences in cell morphology between Ax2 cells and
dymA cells led us to examine the
ultrastructure of dymA cells at light and
electron microscopic levels. Transmission electron micrographs showed a
striking accumulation of membrane tubules in proximity to nuclei and
the cell membrane in dymA cells (Figures
9 and
10). These spongiome-like structures
could represent sections through convoluted vesicular or tubular
profiles. Additionally, coated vesicles (90-150 nm) or pits could be
readily detected in electron microscopic (EM) micrographs of
dymA cells, and the number of coated
structures appeared higher than in wild-type cells. Coated vesicles
were observed in association with spongiome-like structures and were
particularly enriched near the MTOC (Figure
10, A and B). Coated pits were
frequently found on vesicular or tubular structures near the plasma
membrane but not at the plasma membrane itself (Figure 10, C and D).
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The localization of proteins related to the endo-lysosomal system and
the Golgi complex was investigated by immunofluorescence, to identify
the nature of the spongiome-like compartment (Figure 11). No differences were observed for
endosomal compartments that can be detected with an antibody that
recognizes the actin-binding protein coronin (De Hostos et
al., 1991). However, when anti-vacuolin antibody 221-1-1 was used
for staining late endosomal compartments (Rauchenberger et
al., 1997), the immunofluorescence pattern in dymA cells was clearly altered. Two to four
late endosomes of similar size were observed per nucleus in Ax2 cells.
In contrast, the number of stained vesicles per nucleus is increased to
10 or more in dymA cells. The
vacuolin-positive compartment of dymA cells is
more variable in size and seems to form a tubular network compared with
the discrete ring-like structures observed in Ax2 cells (Figure 11, A
and A'). Cellular localization of GFP-dynamin A by immunofluorescence
microscopy produced a similar, but more punctate, labeling of
membranous structures, and double immunofluorescence showed an almost
complete colocalization of vacuolin and dynamin A (Figure 11B). The
organization of the Golgi apparatus was visualized using antibody
190-340-8 (Weiner et al., 1993). Perinuclear structures with
short tubular extensions were observed in Ax2 (Figure 11C). The
perinuclear Golgi network appeared somewhat enlarged in the dymA cells, and there was a higher background
of diffuse staining throughout the cells. The increase in diffuse
background staining was also observed in mononucleate
dymA cells of comparable size to the wild-type
cells. In larger, multinucleated dymA cells
the prominent juxtanuclear labeling of all nuclei indicated that each
was associated with a Golgi complex (data not shown).
|
The effects of dymA disruption were not restricted to the
endo-lysosomal system. Normally mitochondria are dispersed uniformly throughout the cytoplasm of D. discoideum cells. In
dymA cells, mitochondria form continuous
reticular structures of variable diameter that consist primarily of
tubules and are branched at multiple points (Figure
12). The striking difference in
mitochondrial morphology was best visualized by indirect
immunofluorescence (Figure 12, A and A') using an anti-porin antibody
(Troll et al., 1992). Clusters of mitochondria and
mitochondria forming continuous reticular structures could also be
readily observed in living dymA cells by phase
contrast microscopy or after appropriate fixation by electron
microscopy (Figure 12, D-F). In addition to these morphological changes, loss of dynamin A expression appears to affect mitochondrial function. The activity of the respiratory chain-marker enzyme, succinate dehydrogenase, was approximately twofold reduced (47 ± 8%) in homogenates of dymA cells when
compared with wild-type cells.
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The EM micrographs also indicated differences in the size and shape of
cell nuclei between dymA cells and the
parental Ax2 cells. Cells were stained with the DNA-specific dye DAPI
to further investigate these differences in nuclear morphology (Figure
12, B, B', C, and C'). On average, the nuclear diameters determined for
dymA cells (3.4 ± 0.8 µm; n = 376) and Ax2 cells (3.3 ± 0.5 µm; n = 212) were similar.
However, ~2% of dymA nuclei measured 6-8
µm in diameter while none of the Ax2 nuclei was larger than 6 µm,
and only one was larger than 5 µm. In addition to the occurrence of
large nuclei in populations of dynamin A-depleted cells, DAPI-stained
dymA nuclei can easily be distinguished from
wild-type nuclei by their lobed appearance, indicative of a difference
in chromatin organization, and aberrant shape.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
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Dynamin A represents a new member of the family of dynamin-related
proteins. The results presented here establish that this D. discoideum protein shares hallmark features, such as the
tripartite GTP-binding motif, the consensus pattern LPRGSGIVTR, and a
high degree of sequence identity with the N-terminal half of other dynamin-like proteins (Figure 1). The C-terminal half of dynamin A
contains sequence motifs that could potentially serve roles similar to
those of the PRD and GED of dynamin-1. However, the organization of
these regions in the polypeptide chain of dynamin A differs from that
of dynamin-1. Dynamin A contains a QNS-rich domain, and similar
asparagine and glutamine repeats have been found in several other
D. discoideum proteins, e.g., protein tyrosine phosphatase
PTP3 (Gamper et al., 1996) and the catalytic subunit of
cAMP-dependent protein kinase PKAC (Burki et al., 1991; Mann and Firtel, 1991). The significance of these repeats is not well understood, but it has been speculated that glutamine repeats may form
polar zippers that make protein oligomerize or able to interact with
other proteins containing glutamine repeats (Stott et al.,
1995). Huntington's disease and six other neurodegenerative diseases
have been linked to abnormally expanded stretches of polyglutamine in
the affected proteins.
Phylogenetic analysis places dynamin A in the same branch as the yeast
proteins, Vps1p and Dnm1p, and the mammalian proteins, DVLP and DLP1.
In primary structure and domain organization, dynamin A is more closely
related to DLP1 and Dnm1p than dynamin-1. So far, little is known about
the biochemical and structural features of this group of dynamin-like
proteins. The members of this group of dynamin-like proteins appear to
support vesicle trafficking processes at cytoplasmic sites distinct
from the plasma membrane. Vps1p is associated with the Golgi and is
required for proper sorting of proteins to the yeast vacuole (Vater
et al., 1992; Wilsbach and Payne, 1993; Nothwehr et
al., 1995). Dnm1p is mostly cytosolic and believed to function
primarily in the maintenance of yeast mitochondrial network morphology
(Shaw et al., 1997). Human DVLP is predominantly found in
the perinuclear region, but its precise role and membrane localization
are unknown (Shin et al., 1997). Rat DLP1 is predominately
found in the soluble cytosolic fraction, but a substantial amount
associates with endoplasmic reticulum tubules and vesicles that move
unidirectionally from the cell periphery toward the perinuclear region;
it may function in the transport of peripheral endoplasmic
reticulum elements to the Golgi compartment (Yoon et
al., 1998).
To gain insight into the cellular function of dynamin A, we used gene
replacement techniques to create D. discoideum cells that no
longer produce the protein. The resulting dymA
cells were viable under all conditions tested, indicating that the
dymA gene product is not essential for D. discoideum growth. However, dynamin A-deficient cells displayed
pleiotropic phenotypic changes in comparison to the parental Ax2
wild-type cells.
In agreement with a role of dynamin A in vesicle sorting and
trafficking, the ability to internalize fluid phase markers by pinocytosis was reduced in dymA cells. Both
the initial rate of uptake and the extent to which the marker was
accumulated were affected. At the same time efflux of the fluid phase
marker was normal, indicating dynamin A participates in endosomal
trafficking, but not in recycling of internalized fluid. The prolonged
transit time for fluid phase in the dymA cells
indicates that the intracellular processing of fluid phase cargo is
altered. Immunofluorescence analysis was used to further dissect the
defect in endocytosis. Coronin, a cytoplasmic actin-associated protein
and a marker of endocytic compartments, is strongly enriched in a
cytoskeletal coat that transiently surrounds both particle- and
fluid-containing vacuoles in D. discoideum (Maniak et
al., 1995; Hacker et al., 1997). Within the first
minute after internalization, both coronin and actin are gradually
released from the phagosome or macropinosome. After dissociation of the
cytoskeletal coat, acidification and digestion of the vesicle contents
occur. The rapid acidification to pH 5 is followed by neutralization
and reassociation with a cytoskeletal coat. The ingested cargo is thus
progressively shuttled to a large, neutral compartment that acquires
fluid-phase markers 60-80 min after endocytosis, just before
exocytosis (Rauchenberger et al., 1997). While the cellular localization of coronin and the frequency of coronin-associated vacuolar structures appeared unchanged, the vacuolin-decorated, postlysosomal compartment was greatly enriched in dynamin A-depleted cells and may, at least in part, account for the accumulation of large
vacuoles (>300 nm) and tubular structure in these cells (Figures 9 and
10). The colocalization of dynamin A and vacuolin supports the idea
that dynamin A might be required for the breakdown of the
vacuolin-decorated postlysosomal vesicles.
The role of mammalian dynamin-1 in clathrin-mediated endocytosis
is well established (Herskovits et al., 1993; van der Bliek et al., 1993; Damke et al., 1994). It was shown
that fluid-phase uptake is affected in a HeLa cell line expressing a
temperature-sensitive dynamin mutant. However, after shift to the
nonpermissive temperature, these HeLa cells rapidly and completely
compensate for the loss of clathrin-dependent endocytosis by inducing
an alternate endocytic pathway (Damke et al., 1995; Lamaze
and Schmid, 1995). In contrast, pinocytosis is constitutively impaired
in D. discoideum cells lacking either dynamin A or the
clathrin heavy chain (O'Halloran and Anderson, 1992; Ruscetti et
al., 1994). Apart from this reduced activity in pinocytosis, the
dymA and CHC mutants display a
spectrum of common and separate defects.
CHC and dymA cells share a
defect in cytokinesis. However, while CHC cells are
unable to grow in suspension cultures and fail to divide due to an
inability to form a functional contractile ring during cell division
(Niswonger and O'Halloran, 1997a), dymA cells
grow in suspension culture and pass through all stages of cytokinesis
up to the formation of the midbody. Only the final step, severing of
the thin cytoplasmic bridge connecting the incipient daughter cells, is
inhibited in dymA cells. A distinct defect of
the CHC cells is the lack of a contractile vacuole and
the resulting impairment in osmoregulation. In contrast, the
contractile vacuole system of dymA cells was
found to be fully functional, and its morphological organization was
similar to that of wild-type cells. The developmental program is
affected both in CHC and dymA
cells. It was demonstrated that clathrin increases the efficiency of
early development and is essential for differentiation of mature spore
cells (Niswonger and O'Halloran, 1997b). Dynamin A-deficient cells
show a comparable defect in the early stages of development; however,
progress from the formation of a pseudoplasmodium to the culmination of
the fruiting body was normal. Fruiting bodies formed by dynamin
A-deficient cells display significant morphological alterations, but
they are still capable of producing viable spores, although spore
viability is reduced to 10-20% of wild-type levels. Finally, while
CHC cells display defects in sorting and secretion of
lysosomal enzymes (Ruscetti et al., 1994), this pathway does
not seem to be affected by disruption of dymA. Lysosomal
-mannosidase is processed normally and apparently not missorted in
dymA cells, and secretion of mature forms of
the enzyme also appears to be normal (data not shown).
The strong impairment in endocytosis of fluid phase markers in
CHC mutants suggested initially that fluid entry proceeds
in D. discoideum mainly through clathrin-mediated
endocytosis (O'Halloran and Anderson, 1992). However, a number of
recent studies indicate that, in D. discoideum, fluid-phase
uptake proceeds predominantly by macropinocytosis and that the
reduction in pinocytosis capacity of axenically grown CHC
cells is caused by cross-talk between the actin- and clathrin-dependent routes of fluid entry during endocytosis (Adessi et al.,
1995; Hacker et al., 1997). Similarly, the observed
reduction in the uptake of fluid-phase markers by
dymA cells may be an indirect effect of
dynamin A depletion. This interpretation is best supported by the
observed distribution of coated structures in
dymA cells and is in agreement with a general
role of dynamins in the budding of vesicles from membranous structures
and vesicle scission (Hinshaw and Schmid, 1995; Takei et
al., 1995). The absence of coated pits from the plasma membrane
and the prominent and frequent occurrence of coated pit-decorated
vesicles (Figure 10D) support the hypothesis that, in D. discoideum, fluid-phase uptake is an actin-dependent process and
that dynamins play a role in the breakdown of macropinosomes and
endosomes rather than the direct entry of extracellular fluid (Aubry
et al., 1997).
Pleiotropic effects of shibire and dynamin-1 mutations are
well known (Poodry et al., 1973; Chen et al.,
1991; van der Bliek et al., 1993). Depletion of the closely
related yeast Dnm1p, which, like dynamin A and DLP1, is mostly
cytosolic, results in a twofold delay in the transport of
endocytic material to the vacuole (Gammie et al., 1995).
However, recent studies provide strong evidence that Dnm1p localizes to
the tip of mitochondria and functions primarily in the maintenance of
yeast mitochondrial network morphology (Shaw et al., 1997).
Functions unrelated to vesicle trafficking have also been reported for
the dynamin-like yeast proteins, Vps1p/Spo15p and Mgm1p. Vps1p/Spo15p
is required for the timely separation of spindle-pole bodies in meiosis
(Yeh et al., 1991), while Mgm1p is needed for the
maintenance of the mitochondrial genome (Jones and Fangman, 1992; Guan
et al., 1993), respectively. Our findings imply that dynamin
A is likely to function in vesicle-trafficking processes related to the
endo-lysosomal system of D. discoideum. The observed
alterations in mitochondrial and nuclear morphology on dynamin A
depletion are probably indirect consequences of a more general defect
in membrane transport processes. This view is supported by the
morphological alterations of the postlysosomal compartment in
dymA cells (Figure 9), a strong increase in
the number of coated structures decorating intracellular membrane
compartments in dymA cells (Figure 10), and
the finding that GFP-labeled dynamin A colocalizes mostly with
vacuolin-decorated membranes and does not colocalize with either nuclei
or mitochondria (Figure 11).
Further investigations will be greatly facilitated by the fact that D. discoideum is readily accessible by biochemical, cell biological, and molecular genetic approaches. This will help to clarify the involvement of dynamin A in cytokinesis and define the exact role of the protein in vesicle targeting and transport processes.
Accession Numbers
Dynamin A sequences reported in this article have been submitted to the GenBank/EMBL data bank with the accession numbers Q94464 for the peptide sequence and X99669 for the nucleotide sequence.
. (C) Sequence alignment of
the putative GTPase effector domains of dynamin A, human dynamin-1, and
the shibire gene product. (D) Diagram of dynamin A
structural domains. The GTPase domain is shown in solid black, and the
tripartite GTP-binding motif is indicated as white bars. LZ, leucine
zipper; GED, GTPase effector domain; QNS,
glutamine-asparagine-serine-rich domain. The basic, proline-rich part
of the QNS-rich region, corresponding to residues 573 to 624, is shown
in dark gray.
