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The Journal of Neuroscience, July 15, 2001, 21(14):5130-5138
The Leukocyte Common Antigen-Related Protein Tyrosine Phosphatase
Receptor Regulates Regenerative Neurite Outgrowth In
Vivo
Youmei
Xie,
Tracy T.
Yeo,
Cheng
Zhang,
Tao
Yang,
Michelle A.
Tisi,
Stephen M.
Massa, and
Frank M.
Longo
Department of Neurology, University of California, San
Francisco/Veteran's Administration Medical Center, San Francisco,
California 94121
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ABSTRACT |
Drosophila and leech models of nervous system
development demonstrate that protein tyrosine phosphatase (PTP)
receptors regulate developmental neurite outgrowth. Whether PTP
receptors regulate neurite outgrowth in adult systems or in
regenerative states remains unknown. The leukocyte common
antigen-related (LAR) receptor is known to be present in rodent
dorsal root ganglion (DRG) neurons; therefore, the well established
model of postcrush sciatic nerve regeneration was used to test the
hypothesis that LAR is required for neurite outgrowth in the adult
mammalian nervous system. In uninjured sciatic nerves, no differences
in nerve morphology and sensory function were detected between
wild-type and LAR-deficient littermate transgenic mice. Sciatic nerve
crush resulted in increased LAR protein expression in DRG neurons. In
addition, nerve injury led to an increase in the proportion of LAR
protein isoforms known to have increased binding affinity to
neurite-promoting laminin-nidogen complexes. Two weeks after nerve
crush, morphological analysis of distal nerve segments in LAR-deficient
transgenic mice demonstrated significantly decreased densities of
myelinated fibers, decreased axonal areas, and increased myelin/axon
area ratios compared with littermate controls. Electron microscopy
analysis revealed a significant twofold reduction in the density of
regenerating unmyelinated fibers in LAR / nerves distal to the crush
site. Sensory testing at the 2 week time point revealed a corresponding
3 mm lag in the proximal-to-distal progression of functioning sensory
fibers along the distal nerve segment. These studies introduce PTP
receptors as a major new gene family regulating regenerative neurite
outgrowth in vivo in the adult mammalian system.
Key words:
LAR; protein tyrosine phosphatase receptor; PTP; nerve
regeneration; sciatic nerve; dorsal root ganglion; neurite
outgrowth
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INTRODUCTION |
Evidence that protein tyrosine
phosphatase (PTP) receptors regulate neurite outgrowth in
vivo has been derived primarily from insect models (for
review, see Desai et al., 1997 ; Stoker and Dutta, 1998; Van Vactor,
1998; Chisholm and Tessier-Lavigne, 1999; den Hertog, 1999;
Bixby, 2000). Studies of Drosophila mutants show that the
Drosophila leukocyte common antigen-related (Dlar) PTP
receptor modulates neurite pathfinding during development (Krueger et
al., 1996; Sun et al., 2000). Null-mutant crosses suggest that Dlar
influences signal transduction of Robo, DCC, cadherin, and other
neurite-modulating receptors and that the phosphorylation of Ena, a
regulator of growth cone actin polymerization, is controlled by
opposing actions of Dlar and the Abl tyrosine kinase (Wills et al.,
1999a,b; Bashaw et al., 2000; Lanier and Gertler, 2000).
Drosophila studies also demonstrate that Dlar and Abl
interact with Trio, a regulator of the Rac and Rho GTP-binding proteins
that in turn control actin assembly and neurite outgrowth (Bateman et
al., 2000; Liebl et al., 2000; Lin and Greenberg, 2000). Inhibition of
HmLAR2, the leech ortholog of Dlar, leads to neurite navigational
errors and growth cone collapse (Gershon et al., 1998; Baker and
Macagno, 2000; Baker et al., 2000).
Less is known regarding PTP receptor function during neurite outgrowth
in mammalian systems. Leukocyte common antigen-related (LAR) mRNA is
expressed in neurons (Longo et al., 1993; Schaapveld et al., 1998), LAR
protein is present along neurites and in growth cones (Honkaniemi et
al., 1998; Zhang et al., 1998), and LAR alternative splicing is
coordinated in a spatiotemporal manner during development (Zhang
and Longo, 1995). Links between mammalian LAR and regulation of the
actin cytoskeleton are suggested by the findings that LAR binds to Trio
in mammalian cells and that Mena, the mammalian ortholog of Ena, is
concentrated at the tips of growth cones (Debant et al., 1996; Lanier
et al., 1999). Studies in two different models of transgenic
LAR-deficient mice reveal decreased cholinergic fiber innervation of
the dentate gyrus (Yeo et al., 1997; Van Lieshout et al., 2000). The
ligand(s) regulating LAR remain unknown, although certain LAR isoforms
bind to laminin-nidogen complexes (O'Grady et al., 1998). Function of
other LAR-type PTP receptors during mammalian neural development is
suggested by the findings of neuroendocrine dysplasia in PTP mutant
mice (Elchebly et al., 1999; Wallace et al., 1999) and altered learning
and long-term potentiation in PTP mutants (Uetani et al., 2000). The
findings that PTP and PTP promote neurite outgrowth in
vitro (Ledig et al., 1999; Wang and Bixby; 1999) will encourage
studies determining whether they also regulate neurite outgrowth
in vivo.
Although Drosophila and murine mutant studies demonstrate
that certain PTP receptors regulate neurite outgrowth during
development, it remains unknown whether PTP receptors modulate
plasticity or regenerative neurite outgrowth in the adult state. The
present study addresses the hypothesis that LAR regulates neurite
outgrowth in the adult in vivo by assessing LAR expression
after nerve injury and by comparing nerve morphology and sensory
function in uninjured and in regenerating nerves in LAR+/+ and LAR/
transgenic littermate mice.
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MATERIALS AND METHODS |
Experimental animals. LAR-transgenic mice containing
a  -galactosidase/neomycin (-geo) reporter transgene in the intron
between exons 6 and 7 of the LAR gene were obtained from Dr. William
Skarnes (Department of Molecular and Cell Biology, University of
California, Berkeley, Berkeley, CA) (LAR transgenic line #534;
Skarnes et al., 1995). The transgene also contains an En-2 splice
acceptor that functions as a "gene trap," resulting in the
expression of a fusion protein containing a small segment of the LAR
extracellular N terminal (the first two Ig-like domains) with the
remainder of the receptor replaced by the -geo protein. The
LAR/-geo fusion protein omits >90% of the LAR receptor, including
the bulk of the extracellular region (the third Ig-like domain along
with the eight FNIII domains) and the entire intracellular region
(phosphatase domains). Northern analysis of mRNA derived from mice
homozygous for the -geo transgene (LAR/) demonstrate only trace
levels of full-length LAR transcripts (Skarnes et al., 1995; Yeo et
al., 1997). The original colony created in the laboratory of Dr.
Skarnes was founded in a 129/Ola/DBA strain background and maintained via successive DBA backcrosses. On arrival in our laboratory, these
mice were bred over a 3 year period by continuing backcrosses with
wild-type DBA. Mice used in the present study were derived via a
minimum of six DBA backcrosses. Genotyping was conducted using reverse
transcription-PCR as described previously (Yeo et al., 1997). LAR+/
littermate crosses were used to generate LAR+/+ and LAR/
littermates. All studies were limited to littermate comparisons, and
mice were studied at 3-5 months of age.
Sciatic nerve crush. Sciatic nerves of anesthetized mice
were exposed bilaterally through a gluteal muscle incision. Nerve compression was performed 2 mm distal to the sciatic notch by placing a
stainless steel rod parallel to the nerve, looping a 6-0 silk suture
around both the rod and the nerve, and pulling the suture firmly for 20 sec. The injured area was marked with a single epineural suture (11-0 silk).
DRG immunostaining. Mice were anesthetized and perfused
through the left cardiac ventricle with heparinized PBS, followed by
100 ml of 4% paraformaldehyde in PBS, pH 7.4. Lumbar dorsal root
ganglia (DRG) were removed and immersion fixed for 3 hr at 4°C in the
same fixative solution. Tissue was cryoprotected with 20% sucrose in
PBS at 4°C overnight and frozen in methylbutane at 30°C.
Fourteen-micrometer-thick sections were cut with a cryostat and mounted
onto Superfrost slides. Sections were incubated with blocking solution
(5% goat serum, 3% BSA, and 0.1% Tween 20 in PBS) for 2 hr at room
temperature, followed by overnight incubation with previously
characterized (Yang et al., 2000) LAR monoclonal antibody (Transduction
Laboratories, Lexington, KY) diluted 1:1000 in 0.1% BSA and
0.1% Tween 20 in PBS. After incubation, sections were washed three
times with PBS and then incubated with Alexa Fluor 488 goat anti-mouse
IgG (Molecular Probes, Eugene, OR) diluted 1:500 in 0.1% BSA and 0.1%
Tween 20 in PBS. Sections were washed three times with PBS, treated
with Prolong Antifade (Molecular Probes), coverslipped, and
photographed using a Zeiss (Thornwood, NY) Axioplan 2 microscope.
Western blot analysis. Tissues were lysed in lysis buffer
(20 mM Tris-HCl, pH 7.5, 137 mM NaCl, 1% Nonidet P-40, 10% glycerol, 500 µM sodium orthovanadate, 1 mM phenylmethylsulfonyl fluoride, 10 µg/ml
aprotinin, and 1 µg/ml leupeptin) for 30 min. Aliquots containing 10 µg of protein were run on 6% SDS polyacrylamide gels with a 5%
stacking gel, followed by transfer to polyvinylidene difluoride
membranes (Amersham Pharmacia Biotech, Arlington Heights, IL).
Membranes were incubated in 5% nonfat dry milk (Bio-Rad, Hercules, CA)
in TBST (20 mM Tris-HCl, pH 7.5, 137 mM, and 0.2% Tween 20) for 1 hr at room
temperature and then incubated overnight with primary antibody. For
detection of LAR, primary antibody consisted of the same monoclonal
antibody directed against the N terminus of LAR (0.5 µg/ml) used
above for immunostaining. LAR isoforms containing the nine residue LAR
alternatively spliced element-c (LASE-c) insert were detected
using previously characterized rabbit polyclonal antibody raised
against LASE-c (1 µg/ml) (Zhang et al., 1998). -Actin was detected
using monoclonal antibody purchased from Sigma (St. Louis, MO). For
monoclonal primary antibodies, secondary antibody consisted of
peroxidase-conjugated goat anti-mouse IgG (1:20,000 dilution; Dako,
Carpinteria, CA). For the polyclonal primary antibody, secondary
antibody consisted of peroxidase-conjugated goat anti-rabbit IgG
(1:20,000 dilution; Pierce, Rockford, IL). Membranes were processed for
chemiluminescence detection using the Amersham ECL detection kit
and exposed to x-ray film for 0.5-5 min to obtain a range of
exposures. Autoradiographs in the linear range were densitometrically scanned.
Light microscopy morphological analysis. Morphological
analysis was conducted using protocols similar to those described by Rath et al. (1995). Mice were anesthetized and perfused through the
left cardiac ventricle with an ice-cold solution of 4%
paraformaldehyde and 2.5% glutaraldehyde in 0.1 M phosphate buffer, pH 7.4. Nerves were removed
with orientation maintained and immersion fixed overnight at 4°C in
the same fixative solution. Tissues were rinsed three times in 0.05 M sodium phosphate buffer, pH 7.4, and post-fixed in Dalton's osmium solution (4% K2Cr2O7, pH 7.35, 3.4% NaCl, and 4%
OsO4 in a 1:1:2 ratio) for 2 hr. Tissues were then alcohol dehydrated,
propylene oxide treated, and infiltrated and subsequently embedded in
Spurr's resin (Polysciences, Warrington, PA).
One-micrometer-thick semithin cross-sections were cut and
stained with paraphenylenediamine. Digital images were captured at a
magnification of 400× using a Nikon (Tokyo, Japan) Labophot microscope
and the microcomputer imaging device Imaging Research Inc. (St.
Catharines, Canada) program. From each cross-section image, two
to four fields, each covering ~104
µm2, were randomly selected for image
analysis. For each field, the circumference of each myelinated axon and
each myelin profile was manually outlined using procedures similar to
those described by Auer (1994). In each section, the average
number of myelinated fibers per field was determined, and the resulting
average number of myelinated fibers per square micrometer was
calculated. Nerve fiber and myelin areas were calculated using NIH
Image and displayed using a histogram format. All morphometry studies
were conducted in a blinded manner using coded sections.
Electron microscopy morphological analysis. Thin
sections were mounted on 300-mesh nickel grids, stained with lead
citrate and uranyl acetate, and photographed with a Philips 10 Bioscan electron microscope operating at 80 kV. For each cross-section, 15 randomly selected electron micrograph fields (encompassing 6-7% of
total nerve cross-sectional area) of tissue area not covered by grid
bars were photographed. Micrographs, each covering an area of 850 µm2, were examined at a final
magnification of 7280×, and the number of unmyelinated axonal profiles
was counted without knowledge of genotype. Profiles of unmyelinated
fibers were readily distinguished from Schwann cell profiles using
criteria (Jenq and Coggeshall, 1984; Gibbels, 1989) widely applied to
nerve regeneration studies (Longo et al., 1986). Characteristic
unmyelinated fibers have relatively low electron density, contain
abundant microtubule profiles, and are surrounded by a relatively
electron-dense axolemma.
Temperature sensitivity assay (hot plate test). Temperature
sensitivity was tested in a blinded manner using the hot plate test
(Kanaan et al., 1996). Sensitivity to heat was assessed by placing mice
on the surface of an aluminum hot plate set to 50°C. The duration
until the mice first lifted their forepaws or hindpaws was recorded.
Sensory nerve regeneration pinch test. The sensory pinch
test was used to evaluate regeneration of functioning sensory fibers (James et al., 1993). After anesthesia and reexposure, the sciatic nerve was pinched with microforceps at increments of 1 mm starting distally and moving proximally until a clear motor reflex response of
the proximal hindleg or paraspinal muscle (nonsciatic nerve dependent)
was obtained. At that point, the distance in millimeters between the
crush site and the stimulus site was measured using a 0.1 mm scale
under a dissecting microscope. Independent measurements by two
individuals, blinded to genotype, were averaged to yield one
determination per nerve.
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RESULTS |
DRG neuronal LAR expression after nerve crush
Previous in situ and immunostaining studies
demonstrated that LAR is primarily expressed by DRG neurons with low or
absent expression associated with non-neurons (Longo et al., 1993;
Haworth et al., 1998; Honkaniemi et al., 1998; Zhang et al., 1998). To determine whether LAR protein continues to be expressed by DRG neurons
after nerve crush, DRG isolated from uninjured animals and 2 weeks
after lesion were processed for LAR immunostaining. Immunostaining was
conducted using a previously characterized monoclonal antibody directed
against the N terminus of the LAR ~150 kDa extracellular subunit. The
pattern of DRG LAR protein expression 2 weeks after injury appeared
similar to that found in uninjured mice (Fig.
1A,B).
LAR was expressed by most neurons, and signal was also evident along
fibers emanating from the DRG. Consistent with Western blot analyses of
LAR/ DRG described below, immunostaining of DRG sections obtained
from LAR/ mice resulted in the absence of signal (data not shown).
LAR protein expression in DRG isolated from uninjured animals and 2 weeks after lesion was also examined via Western blot analysis using the same LAR antibody used for immunostaining. After nerve crush, LAR
protein levels were increased by ~1.7-fold (Fig.
1C,E). In contrast, Western blot analysis using
antibody directed against the LASE-c insert present in the LAR
extracellular domain demonstrated an ~40% decrease in the proportion
of LAR protein isoforms containing LASE-c (Fig.
1D,F).
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Figure 1.
LAR protein in DRG after nerve crush. DRG frozen
sections obtained from uninjured mice (A) and 2 weeks after nerve crush (B) were immunostained
using monoclonal antibody directed against the N terminal of LAR ~150
kDa ectodomain. Staining patterns from both uninjured and postcrush
tissue appear similar and are consistent with previous localizations of
LAR to neurons and neural processes. Scale bar, 0.1 mm.
C-F, Protein extracts were prepared from lumbar DRG
(L4-L6) pooled from eight normal uninjured mice and from eight
mice 2 weeks after bilateral nerve crush. Western blot analysis of DRG
extracts was performed using the same LAR N-terminal antibody used for
tissue immunostaining. Blots were reprobed using antibody directed
against the LASE-c insert present in the LAR ~150 kDa extracellular
domain, followed by antibody to -actin to control for protein
loading. E, The ratio of LAR to -actin signal
increased by 66% (n = 6; Western analyses;
mean ± SE; *p < 0.05; Mann-Whitney rank sum
test). F, In the same samples, the ratio of LASE-c to
LAR signal decreased by 38% (n = 6; Western
analyses; mean ± SE; *p < 0.05;
Mann-Whitney rank sum test).
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Sciatic nerve morphology and function in uninjured
LAR-deficient mice
Transgenic mice containing the -geo transgene in the 5' end of
the LAR gene were shown previously to have markedly decreased levels of
full-length LAR transcripts (Skarnes et al., 1995; Yeo et al., 1997).
These mRNA studies predicted that LAR protein levels would demonstrate
a corresponding decrease. In the present study, Western blot analysis
using LAR N-terminal antibody was used to compare LAR protein levels in
DRG of LAR+/+ and LAR/ littermates. In LAR+/+ DRG, LAR protein was
readily detected, whereas in LAR/ DRG, only trace levels of the LAR
~150 kDa protein were detected (Fig.
2a). Confirmation of decreased
LAR protein levels confirmed that these -geo gene-trap mice could
serve as a model for assessment of nerve morphology and function in the
LAR-deficient state. In uninjured nerves, morphological analyses,
including overall appearance, fiber density, axonal area and myelin
area, detected no differences in phenotype between LAR+/+ and LAR/
littermate mice (Fig. 2b-e). Analysis of axonal area
distributions detected no significant differences between the LAR+/+
and LAR/ nerves (Fig. 2f). Functional analysis of
pain withdrawal responses found no detectable differences in hot plate
reaction times (Fig. 2g). In addition, LAR/ mice were
not found to have skin lesions, signs of self-mutilation, or other
indicators of sensory loss. Thus, morphological and functional observations found no overt evidence of developmental anomalies or
neuropathy in LAR-deficient mice.
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Figure 2.
Uninjured sciatic nerve morphology and function in
LAR+/+ versus LAR/ mice. a, Protein extracts were
prepared from lumbar DRG (L4-L6) pooled from four LAR+/+ and four
LAR/ uninjured mice. Western blot analysis of DRG extracts was
performed using monoclonal antibody directed against the N terminal of
the LAR ~150 kDa ectodomain. Blots were reprobed using antibody
directed against -actin to control for protein loading. Only trace
levels of LAR protein were detected in DRG tissue derived from LAR/
mice. b, Visual examination of 1-µm-thick semithin
cross-sections of uninjured sciatic nerve stained with
paraphenylenediamine revealed no apparent differences in nerve
structure between LAR+/+ and LAR/ mice. Scale bar, 10 µm.
c-e, Quantitative morphological analysis performed on
nerves derived from three mice of each genotype showed no detectable
differences in myelinated fiber density or in axonal and myelin areas.
Mean ± SE. f, Analysis of axonal areas
demonstrated no significant difference in size distributions between
LAR+/+ and LAR/ nerves (p = 0.214;
Kolmogorov-Smirnov test). g, Pain threshold testing
using the hot plate test revealed no detectable differences in
temperature reaction latency between LAR+/+ (n = 11 mice) and LAR/ (n = 8 mice) mice. Mean ± SE.
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Impaired sciatic nerve regeneration in LAR-deficient mice
Postcrush regenerative neurite outgrowth was assessed using the
well established morphometric approaches of measuring density, axonal
area, and myelin area of myelinated nerve fibers (Frykman et al., 1988;
Griffin and Hoffman, 1993; Auer, 1994; Rath et al., 1995). Other
important methods of assessing regenerative fiber outgrowth include
immunostaining with antibodies directed against various
cytoskeletal-associated proteins or monitoring the profile of axonally
transported proteins or markers (Frykman et al., 1988). However, in
transgenic models, the expression of specific marker proteins and/or
rates of axonal transport might potentially be affected by the absence
of the gene of interest independently of actual alterations in
regenerative fiber outgrowth. Thus, the present study applied standard
morphometric measures of nerve regeneration that are not dependent on
expression levels or axonal transport profiles of specific marker proteins.
Preliminary studies in LAR+/+ mice indicated that postcrush
regenerative fiber outgrowth reached a point just distal to the midthigh level at the 2 week time point. To examine morphological profiles over an optimal distance proximal and distal to the crush site
and to most accurately compare regenerative profiles between the normal
and the potentially impaired state at a given time point, the 2 week
time point was chosen for in depth analyses. Visual inspection of
transverse sections harvested 2 weeks after nerve crush suggested a
decrease in the density of myelinated fibers and decreases in axonal
area and myelin area in LAR/ compared with LAR+/+ nerves at the 2 mm and 4 mm points distal to the crush site (Fig.
3).
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Figure 3.
Gross morphology of sciatic nerve 2 weeks after
crush. Two weeks after sciatic nerve crush, 1-µm-thick semithin
paraphenylenediamine-stained cross-sections obtained from LAR+/+
and LAR/ mice at the crush site (0 mm) and at 2 mm increments
distal to the crush site were examined. Gross inspection suggested
decreased density of myelinated fibers in LAR/ sections at the 2 and 4 mm points. In proximal LAR/ sections (0 and 2 mm), axonal
areas and myelin areas also appeared to be reduced. Scale bar, 10 µm.
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Quantitation of total nerve trunk cross-sectional areas did not detect
a significant difference in nerve cross-sectional area between LAR+/+
and LAR/ nerves in either proximal or distal segments (data not
shown). However, consistent with visual inspection, quantitative
analysis of individual fibers demonstrated significant decreases in
myelinated fiber density in LAR/ nerves compared with LAR+/+ nerves
at the 2 and 4 mm points distal to the crush site (Fig.
4A). This decrease in
myelinated fiber density suggested a loss of formation of myelinated
fibers and possibly a loss of fiber outgrowth in LAR/ nerves.
Quantitative analysis also showed significant decreases of axonal area
and myelin area at the crush point and in all distal sections (Fig.
4B,C). Interestingly, in LAR/
nerves, the ratios of myelin area over axonal area were significantly
increased (Fig. 4D). The disproportionate loss of axonal versus myelin areas in LAR/ nerves suggested a primarily axonal rather than myelin deficiency. For each of the parameters of
fiber density, axonal area, and myelin area, there was an ~2-4 mm
proximal-to-distal lag in LAR/ values compared with LAR+/+ values
(Fig. 4A-C). Size distribution analyses of axonal
areas demonstrated significant decreases in the proportions of fibers with larger areas at the 0 mm crush site and at the 2 mm distal site
(Fig. 5).
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Figure 4.
Sciatic nerve fiber density, axonal area,
and myelin area analyses 2 weeks after crush. Two weeks after nerve
crush, cross-sections were obtained from LAR+/+ (open
circles) and LAR/ (filled circles)
nerves at points 2 mm proximal to the crush site (2 mm), at the crush
site (0 mm), and at 2 mm increments distal to the crush site. Six
nerves of each genotype were examined. The number of myelinated fibers
per area, axonal areas, and myelin areas were measured in two to four
randomly selected fields per section. A, The mean number
of myelinated fibers per field was calculated and expressed as the
number of fibers per 104 µm2.
The mean fiber density derived from a given nerve segment and genotype
was calculated. Mean ± SE are shown. At the 2 and 4 mm points,
significant decreases in fiber density in LAR/ compared with LAR+/+
sections were found (Mann-Whitney rank sum test). In addition, in
LAR+/+ nerves, fiber density at the 2 mm point was increased
significantly compared with that at the crush site
(p = 0.008) and the 2 mm proximal site
(p = 0.049). B, Axonal areas
in sections from LAR/ mice were significantly reduced at the crush
site and in all distal sections. Reductions were particularly large at
the crush site and at the 2 mm site (*p < 0.001;
Mann-Whitney rank sum test). C, Myelin areas in
LAR/ mice were significantly increased at the 2 mm proximal
site and significantly decreased at the crush site and all distal
sites. This decrease was particularly evident at the crush site and at
the 2 mm site (*p < 0.001; Mann-Whitney rank sum
test). D, In all sections except the 8 mm distal point,
myelin/axon area ratios were increased in LAR/ mice
(*p < 0.001; Mann-Whitney rank sum test).
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Figure 5.
Histogram analysis of axonal areas. Data collected
for axonal area analysis was plotted in histogram format over the
indicated area ranges. Hatched bars, LAR+/+ values;
black bars, LAR/ values. For each
panel, the inset shows a cumulative
percentage distribution plot of axonal areas. Analysis of axonal area
distributions using the Kolmogorov-Smirnov test demonstrates a highly
significant loss in the proportion of larger fibers in LAR/ nerves
at the crush site (0 mm) and the 2 mm distal site.
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Quantitative analysis of LAR+/+ nerves also demonstrated a significant
increase in myelinated fiber density in sections 2 mm distal to the
crush site compared with that found proximal to the crush point and at
the crush point (Fig. 4A). This pattern of increased
density of myelinated fibers distal to the crush site has been observed
previously and is consistent with the process of individual
regenerating axons forming multiple regenerating fibers, many of which
are aborted during subsequent maturation (Murray, 1982; Jenq and
Coggeshall, 1984; de Medinaceli, 1995). The failure to detect
this increase in LAR/ nerves further pointed to a loss of
regenerative fiber formation in LAR-deficient mice.
The suggestion of a decreased number of regenerating fibers in LAR/
mice found in light microscopy studies was further assessed using
electron microscopy. Blinded counts of electron micrographs were used
to compare the density of unmyelinated axonal profiles in LAR+/+ and
LAR/ nerves at the 2 and 4 mm sites distal to the crush lesion
(Fig. 6). At the 2 mm point, a
significant 15% decrease in unmyelinated fiber counts in LAR/
nerves was detected. At the 4 mm point, a highly significant 42%
decrease in counts in LAR/ sections was found. In addition,
measurements in LAR+/+ nerves, showed that the unmyelinated fiber
density at the 4 mm point was 19% greater than that found at the 2 mm
point, although this increase was not statistically significant.
Increases in numbers of unmyelinated fibers at sites distal to crush
injury, presumably attributable to the formation of multiple
distal fibers from single proximal fibers, have been demonstrated in
previous electron microscopy studies (Iannuzzelli et al., 1995).
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Figure 6.
Electron microscopy analysis of axonal sprouting.
Electron micrographs of LAR+/+ (A) and LAR/
(B) transverse nerve sections 4 mm distal to the
crush site demonstrate typical profiles of unmyelinated fibers
(indicated by the asterisks). Characteristic profiles
have relatively low electron density, contain abundant microtubule
profiles, and are surrounded by a relatively electron-dense axolemma
(Jeng and Coggeshall, 1984; Longo et al., 1986; Gibbels, 1989).
LAR/ sections had lower numbers of unmyelinated fibers per field.
C, Blinded counts demonstrated a significant decrease in
the number of unmyelinated fibers per area in sections 2 mm
(*p < 0.05) and 4 mm (**p < 0.000001) distal to the crush site. Mann-Whitney rank sum test;
mean ± SE; n = 90 fields counted per
genotype. Scale bars, 1 µm.
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Sensory fiber regeneration is impaired in LAR-deficient
transgenic mice
LAR expression studies using in situ hybridization and
immunohistological staining have shown that LAR is expressed by DRG neurons but not by motor neurons (Longo et al., 1993; Honkaniemi et
al., 1998). Because LAR expression was confined primarily to DRG
neurons, functional studies were focused on sensory fiber modalities.
The pinch test is a well characterized function-based technique used
for quantitative assessment of sensory fiber regenerative outgrowth
(James et al., 1993). Application of the pinch test to LAR+/+ and
LAR/ littermates derived from multiple heterozygous crosses
indicated that the distal point at which functioning sensory fibers
could be detected demonstrated an ~3 mm proximal-to-distal lag in
LAR/ mice compared with that measured in LAR+/+ mice (Fig.
7). It was of particular interest to note
the complete lack of overlap in values derived from LAR+/+ and LAR/
nerves. This lack of overlap indicated that the LAR/ associated
trait of slowed sensory regeneration was fully penetrant.
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Figure 7.
Functional testing of sensory fiber regeneration
in normal and LAR-deficient mice. The pinch test was performed 2 weeks
after nerve crush using LAR+/+ and LAR/ littermate mice in a
blinded manner. Results were combined from two independent experiments
using littermates derived from different heterozygous crosses. The
maximum distal distances beyond the crush site at which nerve pinch
responses were detected were as follows: LAR+/+, 7.08 ± 0.14 mm
(n = 18 nerves); LAR/, 3.50 ± 0.17 mm
(n = 10 nerves). p < 0.0001;
two-tailed Student's t test; mean ± SE.
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DISCUSSION |
Expression of LAR in DRG neurons (Longo et al., 1993; Haworth et
al., 1998) and the presence of LAR protein along sciatic nerve neurites
and in growth cones of regenerating cultured neurons (Zhang et al.,
1998) suggested the hypotheses that LAR regulates neurite outgrowth
during nerve regeneration. Because receptors modulating neurite
outgrowth can either promote or inhibit outgrowth, a priori
it was possible that LAR either augments or counteracts regenerative
outgrowth. The persistence of LAR protein expression in DRG neurons
after sciatic nerve injury suggested a role for LAR in promoting rather
than inhibiting neurite outgrowth. This possibility was also suggested
by the observed increase in the ratio of LAR protein isoforms known to
interact with laminin-nidogen complexes. More direct evidence
supporting a neurite-promoting role for LAR was derived from the
morphological observation of impaired sprouting and outgrowth of fibers
and the functional observation of delayed outgrowth of functioning
sensory fibers in LAR-deficient transgenic mice. Potential factors
contributing to this lag in sensory function include decreases in
proximal myelinated fiber density and size, loss of distal unmyelinated fibers, and changes in fiber conduction properties not evident on
morphological studies. These findings constitute the first direct
evidence supporting the hypothesis that LAR, or any PTP, is required
for regenerative neurite outgrowth and function in vivo and
add an important new class of proteins likely to function during
mammalian neural regeneration.
The morphometric features found in the present study point to potential
roles for LAR during regenerative neurite outgrowth. The increase in
the density of myelinated fibers at 2 and 4 mm distal to the crush site
in LAR+/+ nerves is characteristic of regenerative fiber formation that
occurs during the early stages of regenerative neurite outgrowth.
During this process, single fibers give rise to multiple regenerating
unmyelinated fibers, many of which become myelinated by the 2 week time
point (Giannini et al., 1989; de Medinalceli, 1995; Iannuzzelli et al.,
1995). Fibers failing to elongate along adequate distal tracts
degenerate while others persist. The decrease in the density of
myelinated fibers in LAR/ nerves at the 2 and 4 mm points raises
the possibility that LAR contributes to the formation of regenerating
fibers and/or their subsequent elongation. Alternatively, it is
possible that formation and elongation of unmyelinated fibers occurs
equally in LAR+/+ and LAR/ nerves but that myelination fails in
LAR/ nerves. This latter scenario is made less likely by the
finding of consistently increased myelin to axon area ratios in
regenerating fibers in LAR/ nerves. This increase in myelin to axon
area ratio suggests a primary axonal deficiency rather than a primary failure of myelination. Confirmation of an impairment in fiber outgrowth in LAR/ mice was obtained using quantitative electron microscopy, which demonstrated significantly decreased counts of
regenerating unmyelinated fibers in distal sections.
The present morphological findings in LAR-deficient mice of decreased
axonal caliber and delayed neurite outgrowth support current models of
LAR molecular mechanisms. As discussed above, insect and mammalian
studies suggest that LAR regulates activities and phosphorylation
states of -catenin, Abl, Trio, Mena, and possibly other important
proteins regulating actin and peripherin cytoskeletal dynamics relevant
to neurite outgrowth. Given the loss of axonal areas in LAR/
nerves, it is of interest to note that one major factor controlling
axonal caliber is the content, organization, and phosphorylation state
of neurofilament proteins (Hoffman and Griffin, 1993). The present
findings will encourage quantitative assessment of activation and
phosphorylation states of LAR downstream targets in LAR-deficient models.
The significant decrease in the proportion of LAR protein isoforms
containing the LASE-c insert in the fifth FNIII domain of LAR points to
additional mechanisms by which LAR might modulate sprouting and neurite
outgrowth. Studies of recombinant LAR proteins with or without the
LASE-c insert demonstrate that isoforms not containing LASE-c bind to
laminin-nidogen complexes, whereas isoforms containing LASE-c do not
bind (O'Grady et al., 1998). It is of particular interest to note that
laminin is present in the extracellular matrix surrounding regenerating
fibers (Longo et al., 1984) and has a well established role in
promoting sensory fiber neurite outgrowth (Fawcett and Keynes, 1990;
Griffin and Hoffman, 1993). These observations suggest the possibility
that injury-induced downregulation of the proportion of LAR isoforms
containing LASE-c might upregulate LAR interaction with extracellular
laminin-nidogen complexes and thereby contribute to regenerative fiber
formation and/or outgrowth. In future studies, it will be important to
determine the identity of ligands present in regenerating peripheral
nerve that interact with the LAR ectodomain to regulate neurite outgrowth.
The absence of an abnormal phenotype in uninjured adult sciatic nerves
in LAR/ mice indicates that either LAR does not play a major role
during developmental neurite outgrowth or, alternatively, that
abnormalities present during development caused by LAR deficiency are
resolved via compensatory mechanisms. The latter scenario was suggested
in studies of PTP-deficient mice in which Wallace et al. (1999)
noted a decrease in the size myelinated fibers in sciatic nerve
examined at 21 d of age that was no longer detectable in the 6 month age group. Whether regenerative neurite outgrowth in adult PTP
mice is impaired remains to be investigated. The determination of
whether LAR regulates neurite outgrowth during peripheral nerve
development will require studies at multiple developmental time points.
The absence of markedly abnormal phenotypes in various PTP-deficient,
adult noninjury models has led to the conclusion that many PTPs share
"redundant" functions. The major contrast found in the present
study between the relative lack of a detectable phenotype in uninjured
LAR/ nerves and the marked alterations in regenerative and
functional phenotype in LAR/ nerves after injury raises a note of
caution in application of the term redundant. Clearly,
redundancy in a developmental context does not necessarily predict
redundancy in other contexts.
Two standard caveats apply to most current transgenic mouse knock-out
models. First, the site of the transgene in the targeted gene often
allows a small N-terminal or other protein fragment to be expressed.
The presence of a protein fragment encoded by the targeted gene raises
the potential of a "dominant negative" rather than a
deficiency-based mechanism of altered phenotype. The absence of a
detectable abnormal phenotype in uninjured nerves in LAR/ mice
makes this mechanism unlikely; however, a dominant negative effect can
never be ruled out entirely. A second important factor to consider is
the possibility that the abnormal regenerative phenotype observed in
the present LAR/ mice resulted from a unique strain mixture that
was somehow maintained in all LAR/ littermate mice despite multiple
heterozygous crosses. The combination of using of mice having undergone
at least six DBA backcrosses (estimated congenic homogeneity of >95%)
(Silver, 1995), examining littermate controls, and finding a fully
penetrant regenerative phenotype in multiple litters (Fig. 7)
make this mechanism highly unlikely. These alternative, non-LAR
deficiency explanations for the results found in the present study will
also be addressed by assessing nerve regeneration in additional
transgenic models of LAR deficiency. Schaapveld et al. (1997) created
an LAR-deficient mouse in a C57BL/6 strain background via the insertion
of a transgene into the LAR intracellular phosphatase domain.
Preliminary studies of these mice demonstrate impaired sensory sciatic
nerve regeneration after nerve crush (van Lieshout et al.,
1999). The finding of impaired regeneration in a second
LAR-deficient model created in a distinct strain background and derived
via a distinct gene disruption strategy indicates that the impairment
in regeneration found in the present study is likely to be a result of
LAR deficiency per se rather than a result of the alternative
mechanisms proposed above.
The present studies will encourage the production of inducible
LAR-deficient transgenic mice to further assess LAR function in
vivo. The finding of impaired neurite outgrowth during the early
phases of postcrush regeneration will also encourage long-term studies
to determine whether LAR contributes to long-range neurite outgrowth,
synapse formation, and functional recovery of sensory function. These
findings will also encourage the examination of other models of neural
plasticity in LAR-deficient and other PTP-deficient mice.
| |
FOOTNOTES |
Received Jan. 8, 2001; revised April 17, 2001; accepted May 1, 2001.
This work was supported by the Muscular Dystrophy Association, a Paul
Beeson Award from the American Federation for Aging Research, National
Institute on Aging Grant R01 AG09873, and the Veteran's Administration.
Correspondence should be addressed to Dr. Frank M. Longo, Department of
Neurology, V-127, Veteran's Administration Medical Center/University
of California, San Francisco, 4150 Clement Street, San Francisco, CA
94121. E-mail: lfm{at}itsa.ucsf.edu.
C. Zhang's present address: Department of Neurology, Sun Yat-Sen
University of Medical Sciences, Guangzhou 510080, China.
| |
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ABSTRACT
INTRODUCTION
