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Department of Pediatrics, Sections of Leukocyte Biology and Critical Care Medicine, Baylor College of Medicine, Houston, Texas 77030-2600
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Delays in leukocyte localization likely
contribute to diminished host defense in neonates. Understanding the
processes that may be affected has been hampered by the lack of
suitable developmental models. Using intravital microscopy, we directly
examine leukocyte recruitment in a rabbit pup model. In response to
intraperitoneal interleukin (IL)-1
, there were one-third as many
leukocytes that arrested in pup mesenteric vessels and emigrated
compared with adult vessels, although leukocyte flux was not
different. Leukocyte rolling velocity in pups was one-half that
in adults. In response to surgical trauma alone, the number of arrested
pup cells was 15% that of adult cells, although again leukocyte flux
was not different. An anti-L-selectin antibody inhibited rolling
significantly by 60 min for both pups and adults. The effect on arrest
and emigration occurred at significantly earlier times, although the
effect was less in rabbit pups. A primary defect in leukocyte
emigration in the rabbit pup appears to be a failure of the cell to
transition efficiently from rolling to arrest. L-selectin-dependent
adhesion and emigration are decreased, rolling is not, suggesting that at least part of the defect is due to events downstream of the initial tether.
neonate; cell adhesion; intravital microscopy; leukocyte flux; adhesion; emigration
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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THE SUSCEPTIBILITY of human neonates to both localized soft tissue infections and systemic infections due to bacterial or fungal agents has prompted extensive investigations into neonatal host-defense mechanisms. Among the most consistently observed functional abnormalities in the neonate are those related to leukocyte mobility (6, 27). Early studies using "skin windows" in human neonates have shown altered leukocyte exudation compared with older children and adults (34). Neonatal and immature animals, including nonhuman primates, rats, and rabbits, have delayed neutrophil localization into the peritoneal cavity (12, 32), skin (8), and lung (23).
The current conceptual model for leukocyte extravasation incorporates the idea that leukocyte rolling precedes stationary adhesion and that there is a necessary transition from rolling to arrest on the endothelium under flow conditions. Potential molecular mechanisms for deficits in leukocyte localization in the developing host may be linked to abnormal intercellular adhesion. Current studies using in vitro modeling and whole animal studies where the end point is leukocyte accumulation suggest one or more steps may be affected. Leukocyte and endothelial selectins are critical for capturing of the leukocyte from the blood stream and maintaining rolling. A consistently observed abnormality of cord blood neutrophils is a reduction in surface levels of L-selectin (4, 38). The ability of neutrophil L-selectin to bind to fucosylated, sialylated (or sulfated) carbohydrate structures on cell surface glycoproteins contributes to efficient accumulation of neutrophils on monolayers of activated endothelial cells under flow conditions with venular levels of wall shear stress (2, 4, 41). Cord blood neutrophils exhibit reduced ability to accumulate on activated endothelial cells under flow conditions in vitro, and anti-L-selectin antibodies have little ability to diminish peritoneal neutrophil accumulation in response to thioglycollate in 1-day-old rabbits (4, 12). Endothelial P-selectin may also be limited. Lorant and colleagues (32) found that P-selectin was readily observed on peritoneal venules in adult rats following thioglycollate injury but not on venules in neonatal rats. In addition, human umbilical vein endothelial cells (HUVEC) from preterm infants expressed less P-selectin than HUVEC from term infants (32).
The 2-integrins Mac-1 (CD11b/CD18) and LFA-1 (CD11a/CD18) contribute
to the ability of the neutrophil to adhere to foreign surfaces and to
endothelial cells. Diminished function may contribute to the observed
reductions in chemotactic migration in vitro and emigration into
tissues. An observed abnormality of cord blood neutrophils is a
diminished cell content of Mac-1 and a diminished ability to mobilize
this integrin from intracellular stores to the cell surface (3,
5). A second member of the 2-integrin family,
LFA-1 (CD11a/CD18), may also be reduced, but this has been
inconsistently observed.(5, 18, 38) (Landers C. L. and Mariscalco M. M., unpublished observations).
It is unknown whether these observations translate mechanistically into diminished leukocyte accumulation in the neonate. Addressing this question has been hampered by the lack of suitable models allowing observation of these processes directly in vivo. This study aims to provide insights into the steps required for efficient migration in a developmental rabbit model using intravital microscopy. Furthermore, we seek to elucidate the role of L-selectin in this process, because our previous work suggests that L-selectin-dependent function in neonates is diminished (4, 12).
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MATERIALS AND METHODS |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Animals
Time-dated New Zealand White rabbits (Ray Nichols Rabbitry; Lumberton, TX) were used. Term pups were studied between 2 and 7 days of age and maintained with lactating does until the day of experiment. Rabbits weighing 1.5-3.0 kg were used for comparative adult studies. Adult rabbits received water only 24 h before the experiment. This study complied with the National Institute of Health Guidelines for the Care and Use of Laboratory Animals (1996) and was approved by the Animal Protocol Review Committee at Baylor College of Medicine.Reagents
Human interleukin (IL)-1 was purchased from Boehringer
Mannheim Biochemicals (Indianapolis, IN) (43). Monoclonal
antibody (mAb) TS2/4, murine anti-human CD11a (IgG1), was obtained
through American Type Culture Collection (ATCC; Manassas, VA) and
purified from culture supernatants. It does not cross-react with rabbit neutrophils and serves as a control antibody (18). DREG
200 (IgG1), an anti-human L-selectin that cross-reacts with rabbits, was kindly provided by Dr. T. K. Kishimoto (Boehringer Ingleheim Pharmaceuticals; Ridgefield, CT) (12, 42, 43). Endotoxin content was <0.1 ng/mg protein (Limulus Amoebocyte Assay, Cape Cod
Associates). Antibodies for flow cytometry included M1/70 (ATCC, rat
anti-mouse CD11b, IgG2b) (18) and R15.7, an murine anti-canine CD18 that cross-reacts with rabbits, kindly provided by Dr.
R. Rothlein (Boehringer Ingleheim Pharmaceuticals)
(12). Control antibodies for flow cytometry
included CL18/1 (mouse anti-canine [ICAM]-1, IgG1) (40)
and SFR3-DR5 (rat anti-human HLA-DR5, IgG2b, ATCC); neither
cross-reacts with rabbit neutrophils. R15.7, M1/70, CL18/1, and
SFR3-DR5 were biotinylated using sulfo-NHS-biotin (Pierce Chemical;
Rockford, IL) according to manufacturer's instructions.
Flow Cytometry
The expression of L-selectin, CD18, and CD11b (Mac-1) on adult and pup neutrophils was determined by flow cytometry as previously described (12, 18). All mAbs were titrated using flow cytometry (FACS-Scan; Becton Dickinson; Mountain View, CA) to determine the concentration that saturated binding sites of unstimulated and stimulated cells (4). Detection of L-selectin was determined using DREG 200 and FITC-labeled goat anti-mouse IgG antibody (Zymed Laboratories; South San Francisco, CA). Aliquots of blood from animals receiving either TS2/4 or DREG 200 intravenously were reacted with anti-mouse FITC to determine the amount of antibody bound in vivo. Saturation of neutrophil L-selectin by DREG200 received in vivo was confirmed by adding back additional first antibody before the reaction with anti-mouse FITC. CD18 and Mac-1 expression were determined using biotinylated R15.7 and M1/70, respectively, followed by R-phycoerythrin-conjugated streptavidin (Jackson ImmunoResearch Laboratories; West Grove PA). Neutrophils were identified by their characteristic forward and side-scatter pattern. The mean fluorescent intensity for 5,000 particles/sample was obtained using linear amplification. Average mean fluorescent intensity for each sample was normalized against the value of the isotype-matched control.Animal Preparation
Surgical trauma. Rabbits were anesthetized with intramuscular injections of ketamine hydrochloride 25 mg/kg (pups) or 35 mg/kg (adult rabbits) and xylazine 5 mg/kg before all injections and surgical manipulations. Two separate protocols were developed for these investigations. In the protocol of mild surgical trauma, animals were sedated and tracheotomized. Adult rabbits breathed spontaneously, whereas pups were ventilated using an animal respirator (SAR-830 Ventilator, CWE; Ardmore, PA). Body temperature was continuously monitored (Physitemp Instruments; Clifton, NJ) and maintained by external warming. The rabbit was then transferred to a heated Plexiglas viewing platform, and a midline abdominal incision was performed. The terminal ileum was exteriorized from the abdominal cavity and spread over the viewing platform. The mesentery was perfused with warmed endotoxin-free, bicarbonate-buffered saline (pH 7.4) and covered with plastic wrap. All parts of exteriorized gut were covered with buffer-soaked gauze pads. The superfusion buffer and viewing platform were maintained at 37°C. The rabbit and platform were then transferred to the microscope stage.
IL-1 administration.
We also examined leukocyte rolling in animals after intraperitoneal
administration of IL-1. Animals were sedated and received intraperitoneal IL-1 (1 U/g) (43). Three and one-half
hours later animals were resedated. Pups were tracheotomized and
ventilated. Adult rabbits breathed spontaneously. Pups received
internal jugular catheters, and adult animals had catheters placed in
ear veins for fluid and mAb administration. Five minutes before
exteriorization of the mesentery, animals received 1 mg/kg of either
TS2/4 or DREG 200. Physiological saline was infused intravenously at
4-6 ml · kg
1 · h1.
Exteriorization of the mesentery was performed as outlined above. Time 0 (T0) was the point at which
mesenteric manipulation began. Vessel segments were identified and
recorded every 5 min. For each adult rabbit and pup, 8-12 separate
vessel segments were recorded. The parameters were averaged over 15-min
intervals as before. White blood cell counts were determined at the
completion of the experiment. In this model, leukocytes can be seen to
emigrate through the venule wall into the surrounding mesentery.
Leukocytes that had passed through the vessel wall were counted in an
area of 3,200 µm2. This area was arbitrarily defined by
the length of a 40-µm vessel segment and the region 40 µm above and
below this segment.
Intravital Microscopy
Observations of the vessels in the terminal segment of the superior mesenteric artery were made on a Axioskop intravital microscope (Carl Zeiss; Werk Gottingen, Germany) using a NPL Fluotar objective (×25/0.35 numerical aperture, Leitz Wetzler) for transillumination. Continuous video recordings of the microcirculation were obtained from a video camera (model DXC-960MD, 3CCD Color Video Camera, Sony) mounted on the microscope, which projected the image onto a color monitor (Panasonic). The images were recorded (Video Cassette Recorder, VO-9600) for playback analysis. Single unbranched venules with diameters ranging between 20 and 40 µm were selected for the study. Venular diameter (Dv) was measured online using a video caliper (Microcirculation Research Institute; College Station, TX). For each animal, 10-30 separate vessel segments were examined during the 65-min experiment. The venule segments were analyzed, and the data were averaged for each 15-min period. Time 0 was arbitrarily set as the time of the first observation.The number of adherent leukocytes was determined offline during playback of video-taped images and expressed as the number per 60 µm of vessel segment. A leukocyte was considered adherent if it remained stationary for at least 30 s (43). Rolling leukocytes were defined as those white blood cells (WBC) that moved at a velocity less than that of erythrocytes in the same vessel. Leukocyte rolling velocity (VWBC, µm/s) was determined from the time required for a leukocyte to traverse a given distance along the length of the venule. The flux of leukocytes that rolled past a fixed point of vessel segment in 1 min was determined (FWBC, cells/min). The number of leukocytes that continued to maintain a rolling interaction with the vessel at least 60 µm downstream was also determined (RWBC, cells/min). Because leukocytes may roll for only a section of the vessel before rejoining the flow of blood or adhering to the vessel wall, RWBC is a subset of FWBC.
Centerline red blood cell velocity (VRBC, mm/s)
was measured using an optical Doppler velocimeter (Microcirculation
Research Institute). Mean bulk velocity (Vmean)
was calculated from the red blood cell velocity
(Vmean = VRBC/1.6)
(22). Venular wall shear rate (WSR) was calculated based
on the Newtonian definition: WSR = 8(Vmean/Dv), where
Dv is venular diameter (22). The
volumetric blood flow in the vessel segment (Q) was estimated from the
product of venular cross-sectional area and
Vmean, Q = (
Dv2/4)Vmean
(11). The total number of leukocytes that pass the vessel
segment in a defined period of time is estimated from the product of
the volumetric blood flow and systemic leukocyte count, QWBC = Q(WBC). At the completion of the experiment,
blood was drawn via cardiac puncture from the pups, and systemic WBC
count was determined using a Coulter Counter (Coulter Electronics;
Hialeah, FL). Manual differential counts were performed on
Wright-stained smears. Adult animals had blood obtained every 15 min
from 15 to 60 min via ear arterial puncture. Leukocyte rolling flux
fraction at T60 was defined as the percentage of
the total number of leukocytes traversing the vessel segment at
time 60 (QWBC at T60)
that are rolling past a fixed point; i.e., leukocyte flux
(FWBC at T60) (leukocyte
rolling flux fraction = FWBC/QWBC) (11).
Statistical Methods
Data are presented as means ± SE. Statistics were performed using SPSS software (SPSS; Chicago, IL). Variables were analyzed using repeated-measures analysis of variance with time as the within-group factor and the age of the animal and treatment as the between-group factors. If no time effect was noted, data are presented as the estimated marginal means ± SE for that age animal and treatment group. Cell counts and expression of adhesion molecules were analyzed using two-way analysis of variance. Post hoc multiple comparisons were performed using the Bonferroni test if statistical significance was reached. In variables that could be affected by circulating cell counts, data were also analyzed using WBC as a covariant. Statistical significance was set at P < 0.05.| |
RESULTS |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Depressed Leukocyte Emigration in Rabbit Pups in Response to
IL-1 is Primarily Due to Decreased Ability of Immature Leukocytes to
Arrest
(42, 43). Four hours after IL1 administration and 5 min after receiving control mAb (TS2/4), the skin was incised (T0), and the mesentery was isolated and placed
on the viewing platform. We quantified the number of transmigrated
leukocytes in a 3,200-µm2 area surrounding a 40-µm
vessel. In both 1-wk-old and adult animals, the number of emigrated
cells increased significantly over time after mesentery exteriorization
(P < 0.05 and P < 0.001, respectively, Fig. 1). The rate of
increase was greater in the adult than the neonatal animals (i.e.,
there is a within-subject interaction between time and age,
P < 0.001; Fig. 1). At all times after
T15 there were significantly more transmigrated
leukocytes in the adult animal than in 1-wk-old animals. Adult animals
had significantly higher WBC and absolute neutrophil counts (ANC) than
1-wk-old rabbits by T60 (Table
1). As the number of transmigrated
leukocytes could be affected by circulating WBC counts, we reanalyzed
the number of transmigrated leukocytes at T60
using WBC as the covariant. Again, there were still significantly more
emigrated cells in the adult animals compared with the 1-wk-old rabbits
(P < 0.05).
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Leukocyte rolling was characterized several ways in this model. FWBC is the number of leukocytes rolling passed a fixed point on the vessel wall. FWBC did not change over time in either adult or 1-wk-old rabbits. FWBC was significantly greater in adult rabbits than neonatal rabbits (131 ± 9 vs. 43 ± 8 cells/min, P < 0.001). RWBC is the number of leukocytes that continued to maintain a rolling interaction 60 µm downstream past a second fixed point along the vessel wall. FWBC was not significantly different from RWBC in either age group. Therefore, neonatal leukocytes that were captured from the flow stream rolled at least 60 µm further downstream. Because circulating WBC may also impact FWBC, we determined leukocyte rolling flux fraction at T60 (11). Leukocyte rolling flux fraction was not significantly different between 1-wk-old and adult animals (13.2 ± 3.3% vs 15.0 ± 2.8%, respectively). In contrast, VWBC was 50% less in 1-wk-old rabbits compared with the adults (Table 1). The lower VWBC in 1-wk-old rabbits was not the result of changes in microhemodynamics because there were no significant differences in centerline VRBC, vessel diameter, Q, or venular WSR between the two age groups (Table 1).
Although rolling flux fraction was equal between the age groups and
leukocytes rolled slower in younger animals, adhesion was dramatically
reduced in the 1-wk-old rabbits compared with the adults
(P < 0.001, Fig. 2).
Additionally, the number of adherent cells increased over time after
vessel exteriorization in the adult but not in the 1-wk-old animals
(P < 0.05, Fig. 2). When the number of adherent cells
at T60 were covaried for WBC count, adherent
cell number was still greater in the adult rabbits (P < 0.05).
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We examined the expression of L-selectin, Mac-1, and CD18 on circulating leukocytes at T60 using flow cytometry. As reported by us and others in 1-day-old and premature rabbits (12, 37), L-selectin expression was higher on neutrophils from adult animals compared with 1-wk-old animals (P < 0.02) (Table 1). There was no difference in the expression of Mac-1 or CD18 between neonatal and adult animals.
Thus in 1-wk-old rabbits, a primary defect leading to diminished leukocyte emigration is the decreased ability of the leukocyte to transition from a rolling to an arrested cell. This occurs despite dramatically decreased WBC rolling velocity, "adultlike" levels of Mac-1 and CD18, and a rolling flux fraction equal to that of adult animals. Although intrinsic transmigration defects may also occur, the decreased ability to arrest appears to predominate in this model.
Neonatal Animals Have Diminished Leukocyte Arrest After Surgical Trauma.
A low frequency of constitutively rolling leukocytes has been observed in normal skin (24), whereas rolling is virtually absent in undisturbed mesentery (10). Leukocyte rolling is rapidly induced on surgical manipulation of the rabbit and rat mesentery as well as the mouse cremaster muscle (10, 29). Because leukocyte emigration does not appreciably occur in this model, we examined arrest directly without loss of cells from the blood vessel into the surrounding tissue.Adult and 1-wk-old rabbits received no IL- or mAb but were subjected
to surgical manipulation of the bowel only. There was no significant
difference between the WBC counts of the 1-wk-old and adult rabbits 60 min after vessel exteriorization (Table
2). The ANC was less in the 1-wk-old
rabbits, although it was not significant (P = 0.055).
VRBC, WSR, and Q were not significantly different between 1-wk-old and adult rabbits (Table 2).
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In both age groups, FWBC and
RWBC decreased over time (Fig.
3). There were significantly fewer
rolling leukocytes that maintained an interaction with a 60-µm
segment of vessel in the 1-wk-old group (FWBC
vs. RWBC, Fig. 3). This did not occur in the
adult animals. Neither FWBC nor
RWBC was different between the two age groups.
Leukocyte rolling flux fraction at T60 was also
not different between 1-wk-old and adult animals (Table 2). In
contrast, VWBC was significantly increased in
1-wk-old rabbits (Table 2).
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The number of adherent cells did not change over the 60-min observation time. However, the number of adherent leukocytes in the 1-wk-old rabbits was only 15% that of adult rabbits (Table. 2). When the number of adherent leukocytes were covaried for the WBC, there were still significantly fewer arrested cells in the 1-wk-old rabbits compared with the adult rabbits.
In this model, the leukocytes of neonatal animals also failed to transition from rolling to arrest, despite having similar numbers of leukocytes that initially roll as adult animals. However, rolling cells of neonatal animals have a higher rolling velocity, and fewer of them maintain a rolling interaction over at least 60 µm of vessel length compared with adult animals.
L-Selectin-Dependent Adhesion And Transmigration Is Depressed in 1-Wk-Old Animals
In adult rabbits, IL-1-induced peritoneal inflammation results
in L-selectin-dependent leukocyte rolling at 45-60 min after mesenteric manipulation (43). L-selectin-ligand
interactions may also function to activate leukocytes, resulting in
increased adhesion and emigration (17, 20). We previously
demonstrated that 1-day-old rabbits had decreased localization of
leukocytes to the peritoneal cavity after thioglycollate-induced
peritonitis, and this appeared to be due to decreased L-selectin
function (12).
Neonatal and adult animals received the anti-L-selectin mAb (DREG 200)
4 h after receiving intraperitoneal IL-1 and before skin
incision. The animals receiving control antibody (TS2/4) are those
previously described in Depressed Leukocyte Emigration in Rabbit
Pups in Response to IL-1 is Primarily Due to Decreased Ability of
Immature Leukocytes to Arrest. Treatment of animals with DREG200
had no significant effect on either WBC or ANC in either 1-wk-old or
adult animals. L-selectin binding sites were saturated by DREG 200 in
animals because adding back additional DREG200 to whole blood in vitro
did not result in increased binding compared with samples in which DREG
200 was not added. There was no difference within each age group
between the control and DREG 200-treated animals in vessel diameter,
VRBC, or Q over time. WSR was significantly less
in TS2/4-treated 1-wk-old animals compared with the DREG-200-treated
group at T15 only (214 ± 21 vs. 346 ± 23, respectively, P < 0.05) but at no other time.
There was also no difference in WSR in the adult animals between the
two treatment groups (Table 1 and data not shown).
By T45 and T60,
anti-L-selectin mAb inhibited FWBC significantly
in the 1-wk-old and adult animals, respectively (Fig.
4A). There was no difference
in the leukocyte rolling flux fraction at T60 in
the anti-L-selectin mAb-treated 1-wk-old rabbits compared with adult
rabbits (7.5 ± 3.3% vs. 7.6 ± 3.7%, respectively). Thus
anti-L-selectin mAb decreased rolling flux fraction by 50% in both age
groups. Anti-L-selectin mAb had no effect on
VWBC in either the 1-wk-old or adult rabbits
compared with their TS2/4-treated controls (Table 1 and data not
shown).
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Both 1-wk-old and adult animals treated with anti-L-selectin mAb had significantly fewer adherent leukocytes by T30 (Fig. 4B). The effect on adult animals was greater than that of 1-wk-old rabbits (P < 0.05). Anti-L-selectin mAb treatment also significantly decreased leukocyte emigration in both adult and 1-wk-old rabbits as early as T15 (Fig. 4C). The inhibitory effect of anti-L-selectin on emigration was greater over time in both age groups, although the effect was greater in the adult animals compared with the neonates (P < 0.01, Fig. 4C).
Anti-L-selectin mAb decreased FWBC in 1-wk-old and adult rabbits by 45-60 min after vessel exteriorization, as has been reported previously (42, 43). Although the anti-L-selectin mAb also markedly decreased the number of arrested and emigrated cells, this occurred at earlier times. Whereas effects of L-selectin blockade on FWBC was not different between the 1-wk-old and adult rabbits, its effect on adhesion and emigration was less in the 1-wk-old rabbits.
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Observations by our group and others have demonstrated that
newborn and infant animals have delays and/or deficits in leukocyte emigration compared with mature animals (8, 12, 23, 32) and that human neonates also have altered leukocyte exudation compared
with older children and adults (34). Lacking in these and
subsequent studies has been mechanistic insights into leukocyte localization in the developing host in vivo. Using intravital microscopy, we demonstrate here for the first time that at least in
rabbit pups there does not appear to be a defect in the ability of the
leukocyte to be recruited from the blood stream. Rather, once the
neonatal leukocyte is recruited (and rolling), there is a markedly
decreased ability to transition from rolling to arrest, a step
necessary for emigration (28, 39). This is supported by
the following observations. First, in a model of mild tissue trauma,
leukocytes of neonatal animals fail to transition from rolling to
arrest, despite having the same number of leukocytes that roll as adult
animals. Second, in mesenteric venules exposed to intraperitoneal
IL-1 for 4 h, neonatal leukocytes have a diminished capacity to
arrest compared with adult even when the effects of increased WBC are
taken into account and despite a markedly diminished leukocyte rolling velocity.
That the leukocytes of 1-wk-old rabbits appeared to have little difficulty in initiating rolling in inflamed mesenteric vessels in either model was unexpected in light of previous reports, which suggest that "tethering" functions may be depressed in the immature host. In vitro human cord blood neutrophils demonstrate decreased rolling compared with adult cells under shear stress on IL-1-stimulated HUVEC monolayers, in part due to diminished function of L-selectin (1, 4). Cord blood neutrophils also fail to tether and roll efficiently on histamine-stimulated HUVEC, E-selectin, and P-selectin monolayers (1, 4, 33). In response to intraperitoneal thioglycollate, 1-day-old rabbits had decreased accumulation of leukocytes compared with adults, and treatment with the anti-L-selectin mAb had no effect on leukocyte accumulation in these 1-day-old animals, although it did in adult animals (12). Consistent with data presented here on 1-wk-old rabbits, 1-day-old and preterm rabbits have diminished surface expression of L-selectin (12, 37). Lorant et al. (32) observed that neonatal rats in vivo have diminished localization of leukocytes to sterile-inflamed peritoneum, which coincided with a marked inability of the neonatal rats to express P-selectin on the inflamed mesenteric vessels, although it was present in abundance in adult animals (32). We propose that selectin-dependent and -independent mechanisms downstream of tethering appear to be specifically affected in neonatal rabbits.
The mechanisms responsible for the transition from a rolling to an arrested leukocyte under relevant physiological shear is not fully understood. Clearly, selectin-dependent tethering and CD18-dependent adhesion are involved. Mechanisms that may trigger sufficient CD18 integrin activation to permit cell arrest include signaling through selectin binding, chemotactic factor stimulation, and perhaps through LFA-1 binding itself (reviewed in Ref. 39). Our observations in the 1-wk-old rabbit may reside in differences in one or more of these processes. In the mesenteric vessels of 1-wk-old rabbits that have been subjected to surgical trauma only, leukocytes rolled faster and did not maintain a prolonged interaction with the endothelial surface. If transit time (i.e., the period of time it takes to traverse a vessel segment that is reflected in rolling velocity) is the main determinant of efficiency of adhesion and ultimately migration, as suggested by Ley and co-workers (26, 28), then increased transit time and a diminished ability to maintain a rolling interaction would result in fewer cells arresting. In both mouse cremaster and rat mesentery venules, P-selectin appears to be primarily responsible for leukocyte rolling early after tissue trauma (i.e., <60 min) (14, 29). One-week-old rabbits, like rat pups, may be deficient in endothelial expression of P-selectin (32) or alternatively P-selectin-signaling may be affected. We cannot yet examine P-selectin function directly in rabbits due to a lack of suitable blocking antibodies. Although many studies have used an anti-human P-selectin that cross-reacts with that of other species, the mechanism of this antibody is in doubt. Gibbs et al. (15) provided evidence that it does not block lectin functions of P-selectin but rather instead inhibits complement interaction with P-selectin short consensus repeats.
Selectins themselves may function in the transition of leukocytes from rolling to stable arrest by transducing adhesion-augmenting signals in the absence of a tethering function. In mice in which E-selectin function was eliminated, either with blocking mAbs or due to loss of gene product, rolling remained intact, but the number of accumulated cells in the skin and peritoneum was markedly diminished (35). L-selectin is rapidly shed from the surface of leukocytes upon activation. Inhibition of L-selectin shedding in vivo not only results in dramatically decreased leukocyte rolling velocities but also increased number of arrested and transmigrated leukocytes (19, 20). Human neutrophils may also be stimulated in vitro through selectins (or their leukocyte ligands) resulting in increased Ca2+ flux, release of oxidative products, increased adhesion, and emigration through activation of Mac-1 and LFA-1 (9, 17, 44).
As has been been reported by von Andrian and colleagues
(43), anti-L-selectin mAb inhibited the tethering of
leukocytes in IL-1-stimulated mesenteric vessels by 45-60 min
after exteriorization was begun. However, significant inhibition of
arrest and emigration commenced much earlier than the effects on
leukocyte rolling. Thus it appears that for both neonatal and adult
rabbit leukocytes, L-selectin not only serves a tethering function but
also appears to support the transition from rolling to arrest. In
addition, L-selectin-dependent arrest is diminished in younger age
animals. It is unclear whether this is due to decreased expression of
L-selectin and/or a decreased ability to respond to the
L-selectin-dependent signal.
We think it is unlikely that we might we have "missed" a large proportion of fluxing leukocytes, thus underestimating differences between adult and newborn animals or alternatively the effect of L-selectin inhibition on leukocyte tethering. Previous studies in rabbits have used fluorescent techniques combined with stroboscopic epiillumination to determine leukocyte rolling (30, 42, 43). Maximum rolling velocities obtained by this method are considerably higher than those obtained under transmitted light (30). However, with the use of fluorescent techniques, the most frequent rolling velocity class was 20-40 µm/s, well within the range of the cell velocities reported here with transmitted light (31). In addition, in models where the vessels are inflamed with cytokines, such as tumor necrosis factor, rolling velocity is much lower (25, 29).
Recent studies support that factors produced by the endothelium, such as IL-8 and platelet-activating factor, are involved in the process of transition from rolling to arrest because these factors result in CD18-dependent adhesion (36, 45). It is unknown whether there is developmental regulation of these or similar chemokines at the inflammatory site in the immature host.
Stationary adhesion requires activation of CD18 integrins. For most
adhesive functions of neutrophils, LFA-1 (CD11a/CD18) and Mac-1
(CD11b/CD18) are predominantly involved. Studies of neutrophil
emigration through endothelial monolayers in vitro reveal a
significantly greater contribution of LFA-1 than Mac-1 (13). Either integrin, however, is sufficient for stopping
rolling cells, although both are required for prolonged stable adhesion under shear conditions (16, 21). In vivo, leukocytes roll for prolonged periods and distances before becoming adherent
(28). The gradual decrease in rolling velocity before
arrest is CD18 dependent, although the specific contribution of Mac-1
or LFA-1 is unknown (28). In the present studies 1-wk-old
rabbits had diminished leukocyte arrest in response to IL-1 despite
a diminished rolling velocity compared with adults. This may be due to
deficiencies in one or more critical CD18 function. In the neonatal
rabbit model of thioglycollate-induced peritonitis, blocking CD18 had less inhibitory effect on peritoneal leukocyte accumulation in 1-day-old rabbits compared with 14-day-old and adult rabbits
(12). Neutrophils from human cord blood have diminished
emigration under static conditions due to decreased Mac-1 function, but
it is unclear whether this also contributes to decreased arrest and
emigration under shear conditions (7). Further studies
will be necessary to elucidate the contribution of LFA-1 and Mac-1 to
leukocyte arrest in vivo both in adult animals and in the developing host.
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ACKNOWLEDGEMENTS |
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The authors acknowledge the kind gifts of the antibodies from Drs. Takashi Kishimoto and Robert Rothlein and the contributions of Celetta Callaway for production of monoclonal antibodies and the technical and clerical assistance of Maria Hong, Karmen Howard, and Michelle Thomas Sturm. We also thank Drs. Paul Kubes and Samina Kanwar for assistance in establishing the protocol and thoughtful insights.
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FOOTNOTES |
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* M. M. Mariscalco and W. Vergara contributed equally to this paper.
This study was supported by National Institutes of Health Grant NIH-AI-19031.
Address for reprint requests and other correspondence: M. M. Mariscalco, Texas Children's Hospital, Children's Nutrition and Research Center, 1100 Bates St., Rm. 6014, Houston, Texas 77030-2600 (E-mail: marym{at}bcm.tmc.edu).
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
10.1152/ajpheart.00090.2001
Received 16 February 2001; accepted in final form 26 October 2001.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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