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Blood, Vol. 96 No. 3 (August 1), 2000:
pp. 1100-1105
PHAGOCYTES
From the Department of Pediatrics, Division of Hematology/Oncology,
The University of Alabama at Birmingham, School of Medicine,
Birmingham, AL.
To examine the effect of lymphocyte specific protein 1 (LSP1) on
phagocytic cell motility, stable transfection of LSP1-null U937 cell
line with an episomal expression vector carrying the LSP1 complementary
DNA created lines expressing varied LSP1 levels. Mock transfectants
without LSP1 (U937
In its most general sense, cell motility depends upon
dynamic rearrangement of the F-actin-based microfilamentous
cytoskeleton and refers to multiple cellular behaviors, including cell
division or cytokinesis, locomotion, phagocytosis, chromosome movement, and cell spreading. Dynamic rearrangements of the
F-actin-based microfilamentous cytoskeleton are modulated by F- and
G-actin interaction with actin-binding and regulatory proteins that
control changes in the organization of F-actin filaments and the G- to F-actin equilibrium.
Lymphocyte specific protein 1 (LSP1; also known as WP34, pp52, and
leufactin) is a 52-kd F-actin-binding phosphoprotein
expressed in all human leukocytes and leukocytic cells lines except the U937 cell line.1-4 Increased amount of LSP1 (4- to 5-fold
control) and "hairlike" surface projections are 2 of the
characteristics of neutrophils from patients with a unique inherited
disorder: neutrophil actin dysfunction with abnormal 47-kd and 89-kd
proteins (NAD 47/89).5,6 The rare individuals affected by
NAD 47/89 have a congenital defect in neutrophil motility that
predisposes them to recurrent infections. To determine if LSP1 affects
nonmuscle cell locomotion, Howard et al7 have studied the
locomotion of A7 melanoma cells stably transfected to express LSP1.
Resultant LSP1 expression inhibited melanoma cell locomotion and
re-created the motile and morphologic phenotype characteristic of NAD
47/89 neutrophils in this nonleukocyte cell line. However, the effect of normal and elevated LSP1 levels in phagocytic leukocytes is not known.
Since LSP1 is leukocyte-specific and phagocytes are motile, we used an
LSP1-null U937 cell line to examine the effect of normal and high LSP1
level on phagocyte motility and morphology. The U937 cell line is a
myelomonocytic cell line that can differentiate into monocytelike
cells. Dibutyryl cyclic adenosine monophosphate (db-cAMP), a
membrane-permeable analogue of cAMP, induces several functional changes
in U937 cells, including increased expression of C5a and
fMLP receptors, increased random migration and chemotaxis, increased expression of CR3 and FcRII, and increased nonspecific phagocytosis.8-11 Here we report that LSP1 is not expressed
in U937 cells. Stable transfection of U937 cells with pCEP
vector carrying the LSP1 complementary DNA creates unique U937 cell
lines that express similar levels of several important actin-binding proteins (ABPs) and varied levels of LSP1 before and after monocytic differentiation of the U937 with db-cAMP. In the stably transfected cell lines, LSP1 levels similar to those in monocytes increase rates of
cell locomotion but have no effect on cell morphology, while LSP1
levels greater than 4-fold those in monocytes inhibit the
differentiated cell locomotion and cause the formation of surface
projections as described in A7 melanoma cells. In contrast, varied LSP1
expression, high or low, does not significantly affect the transfected
U937 cell division or rate of cell growth. These results show that LSP1
level modulates phagocytic cell motility and differentially affects 2 actomyosin-dependent motile functions in U937 cells. The results
suggest LSP1 is an important regulator of phagocytic leukocyte motility.
Monocyte isolation
Cell culture and transfection
Clonal selection in methylcellulose cultures U937 cell concentration was set at 3 × 104 cells/mL. Increasing cell numbers (5 µL, 15 µL, etc) were mixed with 4 mL of methylcellulose mixture, and then placed in 35-mm tissue-culture plates. The cells were cultured for 5 to 10 days. The individual colonies were picked up and resuspended in 0.5 mL RPMI 1640 and 10% FCS without hygromycin B in a 24-well plate. After 1 to 2 days, 0.15 mg/mL of hygromycin B was added to the medium. Methylcellulose mixture consisted of 10 mL of U937-conditioned medium, 8 mL of FCS, 1 mL of glutamine stock solution, 0.5 mL of 100 × penicillin/streptomycin solution, 20 mL of methylcellulose medium (StemCell Technologies, Vancouver, BC, Canada), 11 mL of RPMI 1640, and 50 U/L of 55 mmol/L -mercaptoethanal (Life Technologies, Grand Island, NY).
Quantitative immunoblot analyses U937 cells or monocytes were solubilized in sodium dodecyl sulfate (SDS) sample buffer. Protein concentration assays, SDS-polyacrylamide gel electrophoresis (SDS-PAGE), and immunoblots with antihuman LSP1 monoclonal antibodies (mAbs) were performed as previously described.6 Quantitative analysis was performed by densitometry as previously described.4Cell locomotion assays Transfected U937 cell lines with variable expression of LSP1 were cultured on glass coverslips and treated with 1 mmol/L db-cAMP for 48 hours. Resulting cells were monocytelike with respect to morphology and histochemistry. Monocytic-differentiated U937 lines are nonspecific esterase-positive (approximately 85%) and generate superoxide as evidenced by reduction of nitroblue tetrazolium (approximately 70%). The cells were put into a Dvorak Stotler chamber, videotaped for 2 hours at 37°C, and tracked to determine the rates of locomotion of 100 cells as a function of LSP1 level as described.12Cell growth and division assays Transfected U937 cell lines with variable LSP1 in log-phase growth were inoculated in identical culture medium at the same density: 1 × 105/mL. The cell counts were done every 24 hours from days 1 to 4 to determine the rates of cell growth. Cell division was documented by differential counts of 500 cells at same-day growth, which were attached on the slides by cytospin and stained with Hoescht 33258 (Sigma, St Louis, MO), to determine the number of cells with 1, 2, or 3 nuclei per cell as a percentage of all cells as a function of LSP1 level.Immunofluorescent staining and microscopy MI-U937 cells were grown for 2 days on the coverslips, which were treated with poly-D-lysine (Sigma Chemical) for 30 minutes at 37°C before using. The cells on the coverslips were rinsed in PBS and then fixed in 5% formaldehyde (Tousimis, Rockville, MD) in PBS at room temperature for 45 minutes. The cells were washed in PBS and treated with 0.3% Triton X-100 (Sigma Chemical) in PBS for 1 minute. The cells were washed in PBS again and incubated in blocking buffer containing 1% bovine serum albumin and 5% goat serum (Sigma Chemical) in PBS at 37°C for 20 minutes. The cells were incubated with anti-LSP1 mAb (7B3.4) at 37°C for 1 hour. The cells were washed with PBS, incubated in the blocking buffer for 5 minutes, and then incubated with goat antimouse immunoglobulin G mAb conjugated with Oregon Green 488 (Molecular Probes, Eugene, OR) for 30 minutes at 37°C. The cells were washed and incubated with Texas Red-X phalloidin in PBS (1/50 dilution) at 37°C for 30 minutes. The cells were washed, mounted in the mounting media (Vectashield, Burlingame, CA), and sealed with nail polish. The samples were viewed in a Leitz fluorescent microscope (Wetzlar, Germany) equipped with a 100× phase contrast Phaco 3 objective, a 100× PL Fluotar objective and selective filters.F-actin and LSP1 quantitation and partitioning MI-U937 cells were washed in PBS, fixed with formalin (3.7%) for 15 minutes, and stained with a cocktail containing lysophosphatidylcholine (100 µg/mL) and NBD-phallacidin (3.3 × 10 7
mol/L) (Molecular Probes, Salem, OR) for 10 minutes as
previously described.13,14 Fluorescence was quantitated by
flow cytometry. Partitioning study of F-actin and LSP1 was performed
with antiactin and anti-LSP1 mAbs as previously
described.13,14
LSP1 is expressed at varied levels in stably transfected LSP1+ U937 cell lines Unlike many actin-binding proteins,15 LSP1 is not expressed in nondifferentiated or differentiated monocytelike U937 cells. However, LSP1-null U937 cells stably transfected with the recombinant pCEP4-LSP1 vector and subcloned express varied levels of LSP1. Immunoblots of transfected cell lines (Figure 1A-B) show LSP1 is expressed at varied levels in transfected cell lines (lane 3 and 5) but not in lines stably transfected with vector only (lane 1 and 2). To produce monocytelike motile cells, transfected cell lines were treated with db-cAMP for 2 days8-11 to induce monocyte differentiation. Since the cytomegalovirus immediate/early gene enhancer/promoter in the pCEP vector contains a functional cAMP-responsive element,16 LSP1 expression was doubled following monocytic induction with db-cAMP (lanes 4 and 6). LSP1 levels in the cell lines were compared with the level in peripheral blood monocytes (lane 7). We selected 3 stably transfected U937 cell lines differentiated to monocytelike cells to examine the effect of LSP1 on locomotion. The LSP1-expression levels observed in the cell lines were absent, equal to levels in a monocyte, and 4-fold the monocyte levels (Figure 1B), and the lines were respectively termed MI-U937, MI-U937+,
and MI-U937++++. Therefore, if known actin-binding proteins
other than LSP1 are expressed in all 3 lines, the U937 cell lines can
serve as useful tools to elucidate the effect of LSP1 on phagocyte
motility.
LSP1+ and LSP1  filamin, gelsolin,
 -actinin, and tropomyosin (Figure 1C)show that after db-cAMP
induction, levels of these actin-binding proteins are similar in the
stably transfected U937 cell lines, which vary in LSP1 level.
Furthermore, the total actin per cell (data not shown) and the total
F-actin levels in cells (Figure 1D) are similar for all 3 U937 cell
lines after monocytic induction. Finally, immunoblots of transfected
U937 Triton-insoluble cytoskeletons show the percentage of total LSP1
partitioned into the Triton-insoluble fraction from cells with low or
high LSP1 level is similar: 15.94 ± 4.21% or
13.68 ± 7.21% (n = 4), respectively. After db-cAMP induction,
the percentages of total LSP1 in MI-U937+ or
MI-U937++++ Triton-insoluble cytoskeletons decrease to
4.32 ± 2.91% or 3.51 ± 1.66% (n = 4), respectively. The
percentages of total cellular actin partitioned into the
Triton-insoluble cytoskeleton (also known as Triton-insoluble F-actin)
are 21.59 ± 1.58%, 14.81 ± 1.93%, and
10.37 ± 7.14% (n = 4) in null, low, and high LSP1 cells, respectively. After db-cAMP induction, the actin in Triton-insoluble cytoskeletons decreases to 13.89 ± 3.28%, 7.28 ± 3.54%,
and 6.12 ± 2.98% (n = 4), respectively. The partitioning of
actin and LSP1 is not statistically significantly different in cells
with low and high LSP1 levels. Therefore, differences in the motile
behaviors and the morphology of the U937 cell lines should reflect the
effect of LSP1 and variations in its level alone.
Morphologic effects of LSP1 on MI-U937 cells depend on the level of LSP1 expression As shown in Figure 2, LSP1 staining is negative in MI-U937, positive in
MI-U937+, and most intense in MI-U937++++. The
cellular F-actin distributes primarily to the cell periphery in
MI-U937 and MI-U937+. These cells remain
round with a smooth surface. In contrast, the MI-U937++++
cells displayed surface projections that contain both F-actin and LSP1.
Since the expression of F-actin, total actin content, and other
critical actin-binding proteins is similar in all cells, the results
show that normal LSP1 levels do not alter cellular cytoskeleton or
morphology. In contrast, increased level of LSP1 causes formation of
surface projections on U937 cells, and the morphologic effect of LSP1
depends on LSP1 level.
LSP1 modulates the rate of cell locomotion in monocyte-differentiated U937 cells Three previous observations suggest LSP1 is an important regulator of phagocyte locomotion. First, NAD 47/89 neutrophils with elevated levels of LSP1 are immotile.5 Second, phagocytic leukocytes express LSP1.4 Third, LSP1 expression at any level in LSP1-null A7 melanoma cells immobilizes the cell.7 To determine the effect of LSP1 on phagocyte locomotion, we determined the rates of locomotion of monocyte-differentiated U937 cell lines MI-U937,
MI-U937+ and MI-U937++++ by direct single-cell
video-tracking in a Dvorak-Stotler chamber as described.12
Briefly, cells in the chamber were video-recorded for 2 hours. In each
video record, at least 100 cells were tracked and the mean distance in
micrometers (µm) traveled during 2 hours was measured. Figure
3A shows the mean distance traveled by the LSP1 and LSP1+ cells lines determined in
3 independent experiments with MI-U937,
MI-U937+, and MI-U937++++ cells. To exclude
biases due to subcloning, the mean distance moved in 3 affected
subclones at each LSP1 level was determined. As shown, the distance
traveled by MI-U937+ cells with normal LSP1 levels
(50.77 + 4.11 µm, n = 3, or
4.23 × 101 µm/min) is 2-fold greater than
that of MI-U937 (23.89 + 2.78 µm, n = 3,
or 2.01 × 101 µm/min), which express no
LSP1. This indicates that normal LSP1 levels enhance the rate of
locomotion of these phagocytes. Furthermore, a 4-fold increase in LSP1
level in the MI-U937++++ cells markedly decreased the mean
distance traveled by these cells (7.78 + 1.11 µm, n = 3, or
0.65 × 101 µm/min) when compared
with either MI-U937 or
MI-U937+. These results show that the effect of LSP1
on phagocyte locomotion is biphasic, enhancing locomotion at normal
LSP1 levels and inhibiting locomotion at elevated LSP1
levels. The result suggests LSP1 expression level modulates the
rate of phagocyte locomotion.
Histograms confirm rate of locomotion of U937 cells varies with LSP1 level Since the pCEP vector used in these experiments is episomal, it is possible the observed rates of locomotion (distance traveled in 2 hours) reflect a mixture of 2 cell populations markedly disparate in locomotive behavior rather than a more "normalized" single cell population with respect to locomotion. Existence of disparate cell populations could lead to incorrect conclusions regarding LSP1 effect. To determine if the rates of locomotion were more "normalized," histograms of the rates of locomotion among 150 cells of each cell line was determined. Figure 3B shows comparison histograms of the rates of locomotion among 150 cells from MI-U937,
MI-U937+, and MI-U937++++ cell lines. As shown
in Figure 3B, the distribution of the rates of locomotion among 150 cells with 3 different LSP1 levels is relatively uniform, and
differences in the distance traveled in 2 hours represents the behavior
of a single average population of cells and not a mixed population of
cells widely disparate in locomotive behavior. Therefore the effect of
LSP1 level on monocyte-differentiated U937 motility is a homogeneous
effect and a uniform characteristic of the cells due to variations in LSP1 level.
LSP1 level does not affect the rate of growth and cell division (cytokinesis) in U937 cells To determine if LSP1 expression affects other motile functions in U937 cells, we determined the effect of LSP1 level on rates of cell growth based on the number of cells produced during a specific time period. Cell growth, as evidenced by increasing numbers of cells, requires actomyosin-dependent cleavage of cells into daughter cells or cytokinesis. The cell lines used varied widely in LSP1 level and were not induced to monocyte differentiation. The LSP1 expression levels observed in the cell lines were absent, equal to levels in a monocyte, and 4-fold greater than a monocyte, and the lines were respectively termed U937, U937+, and
U937++++. These cell lines expressed similar levels of
other actin-binding proteins and had similar amounts of total F-actin
level and total actin content (data not shown) as described for the
MI-U937 cells used to analyze motility. To examine the effect of LSP1
on growth, the U937, U937+, and
U937++++ cells in log-phase growth were placed in culture
at the same density on day 0. Daily for the subsequent 4 days, the cell
growth rate and cell division were analyzed by daily cell counts and by
microscopic review of cells stained with Hoescht stain to determine the
number of nuclei per cell. Cytokinesis defects create multinucleate cells and slow growth because nuclear divisions proceed without cleavage of cells into daughter cells. Increased number of nuclei per
cell and a decreased rate of growth are expected in the cells defective
in this actomyosin-dependent cell function as described for myosin II
mutants in Dictyostelium sp17,18
Figure 4 shows the rates of growth for
these cells. The results indicate that LSP1 level has no effect on the
rate of stably transfected cell growth. In Figure
5, bar graphs show that the average
percentages of cells with 1, 2, and 3 nuclei per cells observed among
500 of the U937, U937+, and
U937++++ cells on day 4 are the same. The results show that
LSP1 affects 2 actomyosin-dependent functions differently. While LSP1
modulates cell locomotion, it has no measurable effect on cytokinesis.
Previous reports from 2 different laboratories used genetically
engineered cell lines to demonstrate that the level and normal function
of at least 3 actin-binding proteins
Submitted August 3, 1999; accepted March 22, 2000.
Supported by National Institutes of Health Grant 5 RO1 Hl56155. L.H. is a Bradford Dean Dixon fellow.
Reprints: Thomas H. Howard, Department of Pediatrics, Division of Hematology/Oncology, The Children's Hospital of Alabama, 1600 7th Ave South, Birmingham, AL 35233.
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
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M. O. Hannigan, L. Zhan, Y. Ai, A. Kotlyarov, M. Gaestel, and C.-K. Huang Abnormal Migration Phenotype of Mitogen-Activated Protein Kinase-Activated Protein Kinase 2-/- Neutrophils in Zigmond Chambers Containing Formyl-Methionyl-Leucyl-Phenylalanine Gradients J. Immunol., October 1, 2001; 167(7): 3953 - 3961. [Abstract] [Full Text] [PDF]
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Top
Abstract
Introduction
),
U937+ (
), and U937++++ ([trio])cells. They
were in log-phase growth and plated with the same density on day 0. The
cell densities were examined on the next 4 days. Results are expressed
as the mean ± SD (n = 3).
