Drug Target Insights 2013:7 9–17

doi: 10.4137/DTI.S11802

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Drug Target Insights

O r I g I N A L  r e S e A r C h

Drug Target Insights 2013:7 9

Impact of Hepatocyte Growth Factor on skeletal Myoblast 
Transplantation Late After Myocardial Infarction

Stacy B. O’Blenes1–3, Audrey W. Li3, Chris Bowen4, Drew DeBay4, Mohammed Althobaiti5 
and James Clarke5
1IWK health Centre, halifax, Nova Scotia, Canada. 2Dalhousie University Department of Surgery, halifax, Nova Scotia, 
Canada. 3Dalhousie University Department of Physiology and Biophysics. 4NrC Biomedical MrI research Lab, halifax, 
Nova Scotia, Canada. 5Dalhousie University Department of radiology, Nova Scotia, Canada.
Corresponding author email: stacy.oblenes@iwk.nshealth.ca

Abstract: In clinical studies, skeletal myoblast (SKMB) transplantation late after myocardial infarction (MI) has minimal impact on left 
ventricular (LV) function. This may be related to our previous observation that the extent of SKMB engraftment is minimal in chronic 
MI when compared to acute MI, which correlates with decreased hepatocyte growth factor (HGF) expression, an important regulator 
of SKMB function. Here, we investigated delivery of exogenous HGF as a strategy for augmenting SKMB engraftment late after MI. 
Rats underwent SKMB transplantation 4 weeks after coronary ligation. HGF or vehicle control was delivered intravenously during the 
subsequent 2 weeks. LV function was assessed by MRI before and 2 weeks after SKMB transplantation. We evaluated HGF delivery, 
SKMB engraftment, and expression of genes associated with post-MI remodeling. Serum HGF was 6.2 ± 2.4 ng/mL after 2 weeks of 
HGF infusion (n = 7), but undetectable in controls (n = 7). LV end-diastolic volume and ejection fraction did not improve with HGF 
treatment (321 ± 27 mm3, 42% ± 2% vs. 285 ± 33 mm3, 43% ± 2%, HGF vs. control). MIs were larger in HGF-treated animals (50 ± 7 
vs. 30 ± 6 mm3, P = 0.046), but the volume of engrafted SKMBs or percentage of MIs occupied by SKMBs did not increase with HGF 
(1.7 ± 0.3 mm3, 4.7% ± 1.9% vs. 1.4 ± 0.4 mm3, 5.3% ± 1.6%, HGF vs. control). Expression of genes associated with post-infarction 
remodeling was not altered by HGF. Delivery of exogenous HGF failed to augment SKMB engraftment and functional recovery in 
chronic MI. Expression of genes associated with LV remodeling was not altered by HGF. Alternative strategies to enhance engraftment 
of SKMB must be explored to optimize the clinical efficacy of SKMB transplantation.

Keywords: cell transplantation, heart failure, myocardial infarction

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O’Blenes et al

10 Drug Target Insights 2013:7

Introduction
Skeletal myoblast (SKMB) transplantation has been 
extensively investigated as a strategy to positively 
influence ventricular remodeling following myocar-
dial infarction (MI). While SKMBs transplanted by 
direct injection improved ventricular function in ani-
mal models of myocardial injury,1,2 a randomized trial 
in patients with chronic MI did not show improved 
ventricular function compared to controls.3 We pre-
viously reported that the timing of SKMB trans-
plantation relative to the MI influences the extent of 
engraftment.4 If SKMB transplantation is delayed until 
a chronic MI scar has developed, there is a 95% reduc-
tion in the volume of engrafted SKMBs compared to 
transplantation immediately after MI.4 This may be 
why in the clinical setting, SKMB transplantation 
into a chronic MI scar does not have a major impact 
on ventricular remodeling.3,5 Strategies to augment 
engraftment of SKMBs transplanted late after MI 
may enhance the utility of this therapy in the clinical 
situation, where the time required for isolation and 
expansion of autologous SKMBs in culture precludes 
immediate delivery after an MI. We observed a cor-
relation between the degree of SKMB engraftment 
and the amount of hepatocyte growth factor (HGF) 
present in the MI, which declined over time.4 HGF 
is the primary regulator of skeletal muscle repair 
by SKMBs.6–9 We showed in vitro that recombinant 
human HGF can augment SKMB proliferation and 
protect against hypoxia and oxidative stress,4 effects 
that may assist SKMB engraftment following trans-
plantation into an MI. Since decreased HGF in the 
MI scar over time correlates with degree of SKMB 
engraftment,4 the aim of this study was to determine 
whether delivery of exogenous HGF could enhance 
engraftment of SKMBs transplanted into a chronic 
MI scar.

Methods
Animals
Inbred Dark Agouti transgenic rats expressing 
β-galactosidase under the CAG promoter (DA-
Tg(CAG-lacZ)30 Jmsk)10 were obtained from the Rat 
Resource and Research Center (Columbia, MO, USA) 
and a breeding colony established at our center. These 
animals have widespread β-galactosidase activity that 
is particularly strong in skeletal muscle (Fig. 1A). We 
maintained inbred transgene positive and wild-type 

Figure 1. Characterization of β-galactosidase staining. representative 
images from X-gal stained tissues and cultured cells. (A) Skeletal muscle 
from transgene positive rats used as SKMB donors showing widespread 
X-gal staining. (B) Myocardium from transgene negative rats identical to 
those which are subjected to coronary ligation and SKMB transplantation 
showing no staining for X-gal. (c) Only a small percentage of SKMBs 
used for transplantation stained positive with X-gal.
notes: Scale bars = 10 mm (A and B) and 70 µm (c).

lines, which were used as SKMB donors and recipi-
ents, respectively. All animals were genotyped prior to 
inclusion in the study using the REDExtract-N-Amp 
Tissue PCR Kit (Sigma Chemical Co., St. Louis, MO, 
USA) according to manufacturer’s instructions and 
the primers GAATCTCTATCGTGCGGTGGTTGA 
(forward) and GCCGTGGGTTTCAATATTGGCTTC 
(reverse). Animals were cared for in accordance with 
the Canadian Council on Animal Care guidelines. 
The Dalhousie University Committee on Laboratory 
Animals approved the experimental protocol.

experimental protocol
The experimental protocol was 6 weeks long (Fig. 2). 
Male transgene negative rats (SKMB recipients, 
approximately 20 weeks old) underwent coronary 
ligation. During week 4, cardiac Magnetic resonance 
imaging (MRI) was performed and SKMBs were 
harvested from male transgene-positive rats (SKMB 
donors, approximately 24 weeks old). Implantation of 

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Impact of hgF on myoblast transplant

Drug Target Insights 2013:7 11

 End-diastole and end-systole were determined based 
on visual inspection of short axis images (Fig. 3). 
Manual planimetry of endocardial contours from 
500-µm thick and short continuous axis slices through 
the entire left ventricle (18 to 20 per heart) was used 
to calculate LV volumes.

Skeletal myoblast isolation and culture
SKMBs were isolated as previously described.4 
Briefly, donor rats were anesthetized and the soleus 
muscles were removed and enzymatically  dissociated. 
Cells isolated by centrifugation were plated in 
 laminin-coated dishes (1 µg/cm2, Sigma) and  cultured 
in Ham’s F-12 media (Invitrogen,  Carlsbad, CA, USA) 
containing 20% fetal bovine serum (FBS,  Invitrogen). 
After 7 days in culture, the cells were  harvested by 
trypsinization and re-suspended in  minimum essen-
tial medium (Sigma) at a final concentration of 
1 × 106 cells/85 µL. This technique yields cells with 
approximately 95% viability according to trypan blue 
exclusion and approximately 90% positive labeling 
with antibodies against desmin, a cytoskeletal protein 
expressed in myoblasts and  myocytes. Only 5% ± 1% 
of cultured cells showed β-galactosidase activity 
(Fig. 1C).

Implantation of osmotic pump  
and skeletal myoblast transplantation
Implantable osmotic intravenous infusion pumps 
(200 µL, 0.5 µL/h, Alzet, Cupertino, CA, USA) were 
loaded with human recombinant HGF (2.5 mg/mL, 
Genentech, San Francisco, CA, USA) in buffer 
(500 mM NaCl, 20 mM Tris-HCl, dextran sulfate 
25 mg/mL) or vehicle control (buffer only) and 
primed overnight (37 °C) in 0.9% NaCl before 
implantation. The activity of HGF used in this exper-
iment for promoting SKMB proliferation had been 
confirmed in a cell culture assay (data not shown). 

LAD ligation 1st MRI

Pump implantation
SKMB transplantation

2nd MRI

Control

HGF

Week 0 2 4 6

Figure 2. experimental protocol. 
notes: SKMB transplantation occurred 4 weeks after coronary ligation. 
hgF or vehicle control was delivered over a two-week period following 
SKMB transplantation by implanted minipump. Cardiac MrI was 
performed before SKMB transplantation and prior to the end of the 
experiment.

Figure 3. Cardiac MrI. representative images from MrI data  showing 
examples of short axis LV chamber contours determined at end 
diastole (A) and end systole (B).
notes: Contours collected at 500 µm intervals throughout the LV were 
used to generate LV volumes. Scale bar = 5 mm.

an osmotic pump carrying HGF or vehicle control, 
and transplantation of SKMBs into MI scars of recip-
ients occurred at the end of week 4. A second cardiac 
MRI was performed at the end of week 6.

Coronary ligation
Rats were anesthetized with ketamine hydrochloride 
(26 mg/kg intraperitoneally), xylazine (4.8 mg/kg 
intraperitoneally), and isoflurane (approximately 2%), 
intubated, and ventilated. The mid-left anterior 
descending coronary artery was ligated through a left 
thoracotomy. Animals were extubated when breathing 
spontaneously. Ketoprofen (5 mg/kg subcutaneously) 
and buprenorphine (0.03 mg/kg subcutaneously, 
every 8 to 12 h × 4 doses) were used for analgesia.

Cardiac MrI
MRI scans were performed using a Magnex  Scientific 
Scanner (Oxford, UK) interfaced with a Direct Drive 
spectrometer (Varian Inc., Palo Alto, CA, USA). 
A custom quadrature radio frequency (RF)  transmit/
receive volume coil was used for  imaging. Rats were 
anesthetized with isoflurane (2%–3%) and were 
spontaneously breathing. A 3D balanced steady-
state, free precession, self-gated sequence adapted 
from a previously described technique11 was used to 
obtain 500 µm  isotropic resolution volumetric images 
(approximately 26 per cardiac cycle). Raw 3D image 
sets were imported into RView (Colin Studholme, 
University of California), de-identified, and pro-
vided to a cardiac radiologist for assessment of left 
ventricular (LV) volumes and ejection  fraction (EF). 

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O’Blenes et al

12 Drug Target Insights 2013:7

Rats were  anesthetized as described above, the left 
jugular vein was cannulated, and a bolus injection 
of HGF (30 µg in 500 µL buffer) or vehicle control 
(buffer only) was administered. The pump cannula 
was secured in the jugular vein and the pump was 
implanted  subcutaneously. Previous thoracotomy 
was reopened and SKMB transplantation was per-
formed as previously described.4 Four injections of 
1 × 106 SKMBs were performed in a diamond pattern 
within each infarct (total of 4 × 106 cells per animal). 
 Animals were recovered as described above.

Sample collection
Rats were euthanized 2 weeks after SKMB 
 transplantation. Serum was collected for assessment 
of HGF concentration. The left ventricle was opened 
longitudinally opposite to the MI, pinned to a dish 
with the endocardium exposed, and fixed in 2% para-
formaldehyde followed by 30% sucrose.  Sections 
(40-µm thick) were cut parallel to the endocardial 
surface using a freezing microtome. Samples of left 
ventricular myocardium remote from the infarct 
were snap-frozen in liquid nitrogen for later mRNA 
 isolation. Remaining fluid in the osmotic pump was 
collected and quantified.

hepatocyte growth factor eLISA
Serum HGF levels were quantified using the Quan-
tikine Human HGF Immunoassay kit (R&D Systems, 
Minneapolis, MN, USA) according to the manufac-
turer’s instructions. A standard curve was generated 
using recombinant human HGF (Genentech). The 
assay has a detection limit of 40 pg/mL.

Immunofluorescence and β-galactosidase 
staining, quantification of infarct size,  
and skeletal myoblast engraftment
Every fifth section through the ventricular wall was 
stained for β-galactosidase activity (NovaUltra Spe-
cial Stain Kit, IHC World, Woodstock, MD, USA) 
according to the manufacturer’s instructions. The 
same sections were then immunofluorescence dou-
ble-labeled as described previously4 with antibodies 
against skeletal myosin to identify engrafted SKMBs 
and connexin 43 to identify surviving myocardium. 
Immunofluorescence staining was quantified using 
a computerized image analysis system as previously 
described.4 Briefly, total infarct area (absence of 

 connexin 43 labeling) and area occupied by engrafted 
SKMB’s (positive for skeletal myosin) was quanti-
fied on each section and the corresponding volumes 
calculated from the entire stack of serial sections.

mrNA isolation and quantitative PCr
Left ventricular myocardium remote from the infarct 
was collected and immediately frozen in liquid 
 nitrogen. RNA was extracted using the Aurum Total 
RNA fatty and fibrous tissue kit (Bio-Rad, Hercules, 
CA, USA), quantified using the Qubit RNA assay 
kit  (Invitrogen), and reverse-transcribed using the 
iScriptcDNA synthesis kit (Bio-Rad). Quantitative 
gene expression was assessed using a CFX96 Real-
Time PCR detection system (Bio-Rad) and SYBR 
Green technology (Bio-Rad). Fibronectin (FN), 
collagen-I (C-I), collagen III (C-III), matrix metallo-
proteinases (MMP)-2 and -9, membrane type 1-MMP 
(MT1-MMP), and monocyte chemoattractant peptide-1 
(MCP-1) gene expression was assessed using the prim-
ers shown in Table 1. PCR conditions were optimized 
for each set of primers. Melting curve analysis showed 
a single PCR product for each gene amplified. The 
PCR cycling profile consisted of an initial denaturation 
at 95 °C for 30 s and 35 cycles of 95 °C (5 s) and 58 
or 60 °C (5 s), depending on the primer set (Table 1), 
for annealing with extension. The housekeeping gene 
glyceraldehyde 3-phosphate dehydrogenase (GAPDH) 
was used for  normalization. Relative gene expression 
was calculated using the 2-∆∆Ct method.12

Results
Coronary artery ligation and skeletal 
myoblast transplantation
Thirty-one rats underwent LAD ligation. Nine (30%) 
died, either from arrhythmia immediately after liga-
tion or from euthanasia due to respiratory distress in 
the post-operative period. Twenty-two rats returned 
to the operating room 4 weeks later for  implantation 
of the osmotic pump and SKMB transplantation. 
Three animals died intraoperatively due to bleeding 
during re-thoracotomy and three died during the post-
operative period (1 control animal and 2 HGF-treated 
animals). Two animals showed no evidence of MI 
and were excluded. A total of 14 rats (7 control and 
7 HGF) successfully completed the protocol. Initial 
weights at the start of the experiment were similar 
(263 ± 8 g for control vs. 270 ± 8 g for HGF), and 

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Impact of hgF on myoblast transplant

Drug Target Insights 2013:7 13

weight changes during the experiment did not differ 
(-8 ± 2 g for control vs. -3 ± 4 g for HGF, P = 0.35).

hepatocyte growth factor delivery
Based on the amount of residual fluid in the osmotic 
pumps at the end of the experiment, 192 ± 11 µL 
of buffer containing HFG was delivered over the 
2-week period. Including the initial 30 µg bolus of 
HGF delivered at the time of pump implantation, the 
amount of HGF delivered over the 2-week period 
was 509 ± 28 µg. Serum HGF levels measured by 
enzyme-linked immunosorbent assay (ELISA) were 
6.2 ± 2.4 ng/mL in the HGF group and were undetect-
able in the plasma of all animals in the control group.

Ventricular dimensions
LV volumes and EF were assessed by MRI before and 
2 weeks after SKMB transplantation (Fig 2). LV vol-
umes and EF did not differ between control and HGF 
groups prior to SKMB transplantation (Table 2). 
There was no progression in LV dilation during 

Table 1. Primer sequences for real-time pCr analysis of gene expression.

Gene primer Annealing 
temp. (°c)

Accession 
number

gAPDh 60 AF 106860
 Forward 5′-ATgACTCTACCCACggCAAg-3′
 reverse 5′-CTggAAgATggTgATgggTT-3′
Fibronectin 60 NM_019143
 Forward 5′-gCgACTCTgACTggCCTTAC-3′
 reverse 5′-CCgTgTAAgggTCAAAgCAT-3′
Collagen I 60 XM_213440
 Forward 5′-TgCTgCCTTTTCTgTTCCTT-3′
 reverse 5′-AAggTgCTgggTAgggAAgT-3′
Collagen III 58 BC_087039
 Forward 5′-gTCCACgAggTgACAAAggT-3′
 reverse 5′-CATCTTTTCCAggAggTCCA-3′
MMP-2 60 NM_031054
 Forward 5′-ACCgTCgCCCATCATCAA-3′
 reverse 5′-TTgCACTgCCAACTCTTTgTCT-3′
MMP-9 60 NM_031055
 Forward 5′-TCgAAggCg ACCTCAAgTg-3′
 reverse 5′-TTCggTgTAgCTT TggATCCA-3′
MT1-MMP 60 –
 Forward 5′-ggATACCCAATgCCCATTggCCA-3′
 reverse 5′-CCATTgggCATCCAgAAgAgAgC-3′
MCP-1 60 –
 Forward 5′-CACCTgCTgCTACTCATTCACT-3′
 reverse 5′-gTTCTCTgTCATACTggTCACTTCT-3′

Abbreviations: gAPDh, glyceraldehyde-3-phosphate dehydrogenase; MMP, matrix metalloproteinase; MT1, membrane type 1; MCP, monocyte 
chemoattractant peptide.

the 2 weeks after SKMB transplantation and slight 
improvement in LV volumes and EF were generally 
observed at the second MRI, although the differences 
were not statistically significant. There were no dif-
ferences between animals that received HGF and 
those that did not (Table 2).

Infarct size and skeletal myoblast 
engraftment
Two weeks after SKMB transplantation (6 weeks 
after MI), the volume of the MI scar and skeletal 
myoblast engraftment were quantified from immu-
nofluorescence labeled histological sections (Fig. 4). 
The volume of the MI scar was larger in HGF-treated 
animals compared with in controls (Fig. 5A, 50 ± 7 
vs. 30 ± 6 mm3, P = 0.046). MIs occupied a larger 
area in the HGF-treated group; however, the differ-
ence was not statistically significant (Fig. 4B, 54 ± 8 
vs. 40 ± 8 mm2, P = 0.24). The volume of engrafted 
SKMBs detected was low and did not increase 
 following administration of HGF (Fig. 5A, 1.7 ± 0.3 vs. 

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O’Blenes et al

14 Drug Target Insights 2013:7

Figure 4. Identification of MI and engrafted SKMBs. (A) representa-
tive merged image from a typical section cut parallel to the endocardial 
surface. The area shown demonstrates surviving myocardium (arrows) 
identified by immunofluorescence labeling using antibodies against 
connexin 43 (green) and engrafted SKMBs (arrow heads) identified by 
immunofluorescence labeling using antibodies against fast skeletal myo-
sin (red). (B) The same sections were also stained for β-galactosidase 
activity (blue). β-galactosidase-positive cells (arrows) were found exclu-
sively in areas containing engrafted SKMBs.identified by fast skeletal 
myosin staining.
note: Scale bar = 100 µm.

Table 2. Cardiac MrI results.

pre- 
sKMBTx

post- 
sKMBTx

Δ (%)

Control
  LVeDV  

(mm3)
312 ± 35 285 ± 33a -27 ± 40 (-2 ± 17)

  LVeSV  
(mm3)

195 ± 21 162 ± 17b -33 ± 30 (-7 ± 19)

  LVeF  
(%)

37 ± 3 43 ± 2c +5 ± 2 (+19 ± 9)

hgF
  LVeDV  

(mm3)
383 ± 55 321 ± 27d -62 ± 56 (-14 ± 16)g

  LVeSV  
(mm3)

249 ± 41 189 ± 29e -60 ± 37 (-17 ± 9)h

  LVeF  
(%)

34 ± 5 42 ± 2f +8 ± 4 (+28 ± 13)i

notes: aP = 0.51 vs. pre-SKMBTx; bP = 0.25 vs. pre-SKMBTx; cP = 0.06 
vs. pre-SKMBTx; dP = 0.31 vs. pre-SKMBTx; eP = 0.26 vs. pre-SKMBTx; 
fP = 0.07 vs. pre-SKMBTx; gP = 0.92 vs. control; hP = 0.69 vs. control; 
iP = 0.60 vs. control.
Abbreviations: SKMB Tx, skeletal myoblast transplantation; LVeDV, 
left ventricular end diastolic volume; LVeSV, left ventricular end systolic 
volume; LVeF, left ventricular ejection fraction.

1.4 ± 0.4 mm3, HGF vs. control, P = 0.58). Similarly, 
the percentage of the infarct scar occupied by SKMBs 
did not increase following HGF treatment (4.7 ± 1.9 
vs. 5.3% ± 1.6%, HGF vs. control, P = 0.81).

expression of genes associated 
with post-MI ventricular remodeling
Expression of genes associated with post-MI 
remodeling19,20 was assessed in LV myocardium 

remote from the MI (Fig. 6). Expression (2-∆∆Ct) of FN 
(5.3 ± 0.3 vs. 5.8 ± 0.2, HGF vs. control), C-I (15.4 ± 0.4 
vs. 14.7 ± 0.4, HGF vs. control), C-III (3.3 ± 0.2 
vs. 3.7 ± 0.4, HGF vs. control), MMP-2 (4.7 ± 0.1 vs. 
5.1 ± 0.2, HGF vs. control), MMP-9 (13.7 ± 0.1 vs. 
12.7 ± 0.6, HGF vs. control), MT1-MMP (7.3 ± 0.1 
vs. 7.7 ± 0.2, HGF vs. control), and MCP-1 (16.6 ± 0.5 
vs. 16.3 ± 0.2, HGF vs. control) was not altered by 
HGF administration.

Comment
In the rat model of MI, infarcts develop into a chronic 
scar by 4 weeks after coronary ligation. In the pres-
ent study, we found that SKMBs occupy only about 
5% of the MI scar when transplantated 4 weeks after 
coronary ligation. This result is consistent with our 
previous report that showed 2.5% of the MI occupied 
by SKMBs transplanted 5 weeks after MI, which is 
a 95% reduction in engraftment compared to when 
the same number of SKMBs were transplanted in the 
setting of an acute MI.4 McCue et al also reported 
that only a small percentage of SKMBs transplanted 
1 month after MI in rabbits can be identified in the 
heart.13 In humans, only about 1% of SKMBs trans-
planted into chronic MIs can be identified through 
histologic examination.14 The limited engraftment 
observed when SKMBs are transplanted into a chronic 
infarct scar may explain the modest benefit observed 
in clinical trials.3,5 Because of the time required to 
expand autologous SKMBs in culture before trans-
plantation, it is not practical to perform transplan-
tation very early after MI. Therefore, strategies for 
augmenting engraftment in the setting of chronic MI 
are necessary for enhancing the clinical impact of this 
therapy.

In our previous study, we found that the extent of 
myoblast engraftment correlated with HGF immuno-
reactivity in the MI scar, which declined over time. 
HGF plays an important role in mediating repair of 
skeletal muscle by SKMBs.6–9 HGF promotes SKMB 
proliferation in vitro4,15 and protects against hypoxia 
and oxidative stress,4,16 conditions that are present in 
MI and heart failure.16–18 We therefore hypothesized 
that delivery of exogenous HGF would enhance 
engraftment and positively influence LV  remodeling. 
However, we found that delivery of exogenous 
HGF did not enhance the extent of SKMB engraft-
ment when SKMBs were transplanted late after MI. 

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Impact of hgF on myoblast transplant

Drug Target Insights 2013:7 15

There was also no impact on ventricular function, 
and the expression of genes associated with post-MI 
ventricular remodeling19,20 in the remote un-infarcted 
myocardium was not altered. In fact, MI volume was 
somewhat larger in the HGF group, but this is likely 
related to variability in the size of the initial infarct 
rather than an adverse impact on remodeling by HGF. 
Ventricular dimensions were stable during the two 
week period following SKMB transplantation and 
were not affected by HGF.

Our results are in contrast with those of Tambara 
et al in which HGF was delivered locally by sustained 
release matrix placed at the time of transplantation of 
5 × 106 skeletal myoblasts 4 weeks after MI (21). In 
control animals, the volume of SKMB engraftment 
was similar to that observed in our study (5 ± 0.7 mm3). 
However, with the addition of local HGF delivery, 
Tambara et al observed an approximately 7-fold 
increase in the volume of engrafted SKMBs, whereas 
we found no impact of HGF delivered systemically. 
While it is possible that neonatal SKMBs used in their 
study behaved differently than the more clinically 
relevant adult SKMBs used in our model, it is also 
possible that the route of HGF delivery is  important. 
In the setting of MI, systemic delivery may not pro-
vide adequate tissue concentrations of HGF within 
the infarct scar. Poppe et al examined the effect of 
transfected neonatal SKMBs  overexpressing HGF on 
LV function and infarct size following transplantation 
2 weeks after coronary ligation.22 Consistent with our 
results, they found that transfecting SKMBs overex-
pressing HGF had no impact on ventricular function 
after transplantation. However, SKMB engraftment 
was not quantified in the study. It is possible that had 
we chosen a local delivery method to target the trans-
planted SKMBs with HGF, we would have observed 
an impact on engraftment rate.

We used a dose of HGF based on a previously 
reported protocol in which human recombinant HGF 
was delivered in rats at a dose of 100 µg/kg/day for 
14 days by osmotic intravenous pump, which was 

60

Infarct

Myoblasts

50

40

30

20

V
o

lu
m

e
 (

m
m

3
)

10

0
Control HGF

*

A

80

60

40

20

A
re

a
 (

m
m

2
)

0
Control HGF

B

1.5

1.0

0.5

T
h

ic
k
n

e
s
s
 (

m
m

)

0
Control HGF

C

Figure 5. Delivering exogenous hgF did not enhance engraftment of SKMBs. (A) graph of total infarct volume and volume of engrafted SKMBs. The total 
infarct volume was somewhat larger in the hgF group. however, the volume of engrafted SKMBs (black bars) was not different in hgF treated animals 
when compared to controls. (B) Graph showing MI area. Average area was not significantly different in animals treated with HGF when compared to 
 controls. (c) Graph showing average thickness of MI. MI thickness was not significantly different in either group.
note: *P , 0.05.

20 Control

2
−

∆
∆

C
t

HGF

15

10

5

0

F
N

C
-I

C
-I

II

M
M

P
-2

M
M

P
-9

M
T

1
-M

M
P

M
C

P
-1

Figure 6. expression of genes associated with LV remodeling in non-
infracted myocardium was not altered by delivery of exogenous hgF.
notes: graph showing gene expression levels of several genes reported 
to be associated with post-MI remodeling. expression levels were similar 
in animals receiving hgF (black bars) and controls (white bars).
Abbreviations: FN, fibronectin; C-I and C-III, Collagen-1 and 3; 
MMP-2 and MMP-9, matrix metalloproteinase-2 and -9; MT1-MMP, 
membrane type 1-MMP; MCP-1, monocyte chemoattractant peptide-1.

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O’Blenes et al

16 Drug Target Insights 2013:7

associated with a biological effect in a model of 
kidney disease.23 While it is possible that a higher 
dose of HGF would alter our results, high con-
centrations of HGF are known to have a negative 
impact on myoblast proliferation by inducing myo-
statin expression.24 Yamada et al demonstrated that 
HGF concentrations of 2.5 and 10 ng/mL have a 
positive influence on SKMB proliferation; how-
ever, beyond this dose range, SKMB proliferation 
is reduced.24 The HGF concentrations used in our 
experiment (6.2 ± 2.4 ng/mL) appear to be in the 
optimal range.

conclusions
In summary, delivery of exogenous HGF by intrave-
nous infusion did not enhance engraftment of adult 
SKMBs transplanted in the setting of a chronic MI 
scar or positively impact LV remodeling. This finding 
is in contrast with a previous report demonstrating 
that local delivery of HGF does enhance engraftment 
of fetal SKMBs transplanted into MIs of a similar 
age. It appears that alternative strategies for enhanc-
ing engraftment of adult SKMBs in the setting of 
chronic MI will be required to optimize the potential 
clinical impact of this therapy.

Author contributions
Conceived and designed the experiments: SO, AL, CB, 
DD. Analysed the data: SO, AL, CB, DD, MA, JC. 
Wrote the first draft of the manuscript: SO. Contributed 
to the writing of the manuscript: SO, AL, CB, DD, MA, 
JC. Agree with manuscript results and conclusions: SO, 
AL, CB, DD, MA, JC. Jointly developed the structure 
and arguments for the paper: SO, AL, CB, DD, MA, 
JC. Made critical revisions and approved final version: 
SO, AL, CB, DD, MA, JC. All authors reviewed and 
approved of the final manuscript.

Funding
This work was funded in part by the Heart and Stroke 
Foundation of New Brunswick.

competing Interests
Author(s) disclose no potential conflicts of interest.

Disclosures and ethics
As a requirement of publication the authors have 
provided signed confirmation of their compliance 

with ethical and legal obligations including but 
not limited to compliance with ICMJE author-
ship and competing interests guidelines, that the 
article is neither under consideration for publi-
cation nor published elsewhere, of their compli-
ance with legal and ethical guidelines concerning 
human and animal research participants (if appli-
cable), and that permission has been obtained for 
reproduction of any copyrighted material. This 
article was subject to blind, independent, expert 
peer review. The reviewers reported no competing  
interests.

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