Protective Effects of Mesenchymal Stem Cells with CXCR4 Up-Regulation in a Rat Renal Transplantation Model

The homing of mesenchymal stem cells to injured tissue, which is important for the correction of conditions such as ischemia-reperfusion injury (IRI) and immunolesions, has been performed previously, but with poor efficiency. Substantial improvements in engraftment are required to derive clinical benefits from MSC transplantation. Chemokines are the most important factors that control cellular migration. Stromal derived factor-1 (SDF-1) is up-regulated during tissue/organ ischemia damage, and its cognate receptor, chemokine receptor 4 (CXCR4), is involved in stem cell migration. The aim of our study was to investigate CXCR4 expression in MSCs and to validate both its role in mediating migration to transplanted kidneys and its immunoregulatory effects in renal protection. Specifically, the present study was designed to investigate the short-term tissue homing of MSCs carrying genetically modified CXCR4 in a rat renal transplantation model. We tested the hypothesis that MSCs with CXCR4 over-expression can more efficiently regulate immunological reactions. Lentiviral vectors were used to over-express CXCR4 or to introduce a short hairpin ribonucleic acid (shRNA) construct targeting endogenous CXCR4 in rat MSCs. MSCs were labeled with enhanced green fluorescent protein (eGFP). After cell sorting, recipient kidneys were regionally perfused; recipient animals were injected with transduced MSCs, native MSCs, or PBS via tail vein following renal transplantation; and the effects of MSC injection were observed.


Introduction
Mesenchymal stem cells (MSCs) have great potential for the treatment of various diseases, especially those involving tissue damage due to immune reactions and ischemia reperfusion injury (IRI) [1][2][3]. Acute/chronic renal failure, particularly renal allograft dysfunction, is associated with high morbidity and mortality [4][5][6]. An increasing number of studies have focused on endogenous and exogenous methods to protect renal function after renal transplantation [7], and MSC-based therapeutic approaches for organ transplantation are promising. Studies show that MSCs can prevent or attenuate ischemic tissue injury in primary transplantation [4,[8][9][10][11]. MSCs are specially characterized by their low immunogenicity and immunoregulatory abilities [12][13][14][15][16][17]. These MSC characteristics are ideal for their use in a renal transplantation model. Some studies have demonstrated that stem cells are capable of forming functional components of kidney [18,19].
However, in vivo strategies with MSCs rely upon efficient localization and retention within the appropriate tissue(s). Current evidence suggests that in the absence of tissue damage, systemically administered MSCs only seed target tissues or organs at low levels [20][21][22][23][24][25][26]. Furthermore, due to localized hypoxia, oxidative stress and inflammation in the targeted tissue, the homing of transplanted cells is very also low and transient, reducing the therapeutic effects [26][27][28]. Thus, it is crucial to identify techniques that can enhance the chemotaxis and retention of implanted MSCs to maximize the effectiveness of MSC-based therapy. It is also important to elucidate MSC immunoregulatory mechanisms in transplanted kidneys. Many studies have demonstrated that stem cell migration and organ-specific homing are regulated by chemokines and their receptors [29,30]. SDF-1 plays a major role in the homing and engraftment of stem cells and progenitor cells to bone marrow and other injured tissues [23,29,[31][32][33]. Its receptor, CXCR4, is highly expressed in MSCs within the bone marrow, but this expression is largely reduced during ex vivo expansion of MSCs [34]. Previous studies have shown that the SDF-1/CXCR4 axis may play an important role in the homing and survival of MSCs [29,33,[35][36][37][38]. However, the therapeutic effects of the SDF-1/CXCR4 axis in renal transplan-tation have not been clearly evaluated, and its detailed mechanism of action is unknown.
The aim of our study was to modulate CXCR4 expression in MSCs and to observe the effects both on secretory action and MSC viability in vitro and on migration and immunoregulation in transplanted kidneys in vivo. The surface expression of CXCR4 was either up-regulated or knocked down in rat MSCs with lentiviral vectors. A rat renal transplantation model was utilized, and the homing, renal protection and paracrine/autocrine functions of these cells were assessed.

Cells isolated from rat bone marrow samples exhibited the properties of MSCs
Primary adherent cells were small and round in the first few days following isolation (Fig. 1A), but later they became larger and polygonal (Fig. 1B). The cells were expanded under normal culture conditions and had a fusiform shape or uniform morphology after several passages (Fig. 1C). Rat MSCs expressed typical markers and differentiation profiles. They strongly expressed CD29 and CD105 but were negative for CD14 and CD45, as shown by flow cytometry analysis (Fig. 1D, E, F, and G). This surface marker pattern was comparable to previous studies and guidelines for MSCs [3,39,40]. Culture-expanded MSCs were also tested for their multi-lineage differentiation potential. In vitro tests using the appropriate inductive culture conditions promoted osteogenic or adipogenic MSC differentiation ( Fig. 1H and I). Thus, the isolated cells met MSC standards mostly [40].

Analysis of transfection efficiency
MSCs were transfected with the sense-strand lentiviral vectors pLV-null-eGFP, pLV-shRNA-CXCR4-eGPF or pLV-CXCR4-eGFP. To confirm the transfection efficiency, MSCs were observed with fluorescence microscopy. Green fluorescent MSCs GFP , MSCs CXCR4/GFP and MSCs shCXCR4/GFP could be observed ( Fig. 2A). The expression of CXCR4 and GFP by MSCs was examined at both the mRNA and protein levels. Expression of the CXCR4 protein was higher in MSCs CXCR4/GFP compared to cells from the control groups (MSCs native and MSCs GFP ) and MSCs shCXCR4/GFP , as determined by Western blot (Fig. 2B). Semiquantitative RT-PCR was performed and revealed that CXCR4 expression was significantly higher in MSCs CXCR4/GFP than in the control groups and was lowest in MSCs shCXCR4/GFP (Fig. 2C). Furthermore, analysis of eGFP expression at the mRNA and protein levels confirmed the transfection efficiency.

Effects of CXCR4 expression on the cellular proliferation of MSCs
In order to investigate the proliferation and cytotoxicity, a standard proliferation and cytotoxicity test, the MTT assay, was adopted to assess mitochondrial viability, and a 5-ethynyl-29deoxyuridine (EdU) incorporation assay was used to investigate DNA synthesis in MSCs infected with either a CXCR4 or shRNA-CXCR4 lentiviral vector for CXCR4 up-regulation or downregulation, respectively. As shown in Fig. 3, knockdown of CXCR4 resulted in significant reductions in MSC viability. (Fig. 3A). EdU incorporation dramatically increased from 28.2% to 42.3% in MSCs CXCR4/GFP (Fig. 3B) and decreased from 11.3% to 7.9% in MSCs shCXCR4/GFP (Fig. 3C). This result indicated that cell proliferation was inhibited with reduced CXCR4 expression and that CXCR4 up-regulation facilitated cell proliferation. Comparison of MSCs GFP and MSCs native showed no difference, demon-strating that the viral vector and eGFP expression did not affect cell proliferation.

SDF-1 expression is up-regulated in transplanted kidneys
In this study, we demonstrated that SDF-1 was up-regulated in an IRI renal model ( Fig. 5 A, B). TheSDF-1 protein levels in transplanted kidneys were observed by enzyme-linked immunosorbent assay (ELISA) at 6 h, 24 h, 48 h, and 72 h after surgery. The results showed that the IRI caused a time-dependent increase in SDF-1 protein levels (Fig. 5C). SDF-1 appeared to increase within the first 6 h after transplant surgery, peaked at 24 h and remained at high levels at 48 h until day 3 after surgery, compared to the levels observed in control kidneys. Pathology score analysis showed a apparently higher injury score in transplanted kidney (Fig. 5 D).

Short-term homing of transplanted MSCs to transplanted kidneys in vivo
To validate the homing of MSCs to target tissue, we looked for eGFP-labeled MSCs 48 h after MSC infusion. Transplanted MSCs could be detected via their eGFP expression by fluorescent microscopy. The migration and distribution of infected MSCs were observed 3 days after the operation. Many eGFP + cells could be found in the transplanted kidneys ( Fig. 6Aa, b, c). The vast majority of eGFP + MSCs were located within the tubules. Some eGFP + MSCs were also found around the lumens of blood vessels. Furthermore, CXCR4 and eGFP expression were examined by quantifying mRNA and protein levels in the kidney via RT-PCR and Western blot, respectively ( Fig. 6B and C). MSCs CXCR4/GFP demonstrated significantly higher levels of CXCR4 and eGFP compared with MSCs GFP and MSCs shCXCR4/GFP . Infused MSCs redistributed not only to the kidneys but also to other organs, including the lungs, spleen and bone marrow. We also detected eGFP expression by measuring mRNA levels via real-time fluorescent quantitation PCR in the lungs, spleen, liver and bone marrow of kidney recipients (Fig. 6D). It appears that CXCR4 over-expression magnified the rate of homing to transplanted kidneys.

Transplantation of MSCs ameliorate transplanted renal failure
Twelve hours after renal surgery, renal function was dissimilarly aggravated in animals receiving MSCs CXCR4/GFP , MSCs shCXCR4/GFP , MSCs GFP , MSCs native , and PBS treatment, as assessed by blood urea nitrogen (BUN) and serum creatinine (Scr) levels ( Fig. 7A and B). The administration of all MSCs improved renal function assessed by Scr in animals at day 3 after transplantation compared to renal function in PBS-treated animals. However, MSCs CXCR4/GFP -treated animals had significantly lower BUN and Scr levels at 48 h after infusion compared with MSCs native -, MSCs GFP -, and MSCs shCXCR4/GFPtreated animals. Renal function was restored to normal levels at 3 days after transplantation in MSC-treated groups ( Fig. 7C and D). BUN levels were also restored to normal levels at 3 days after transplantation in PBS-treated groups. But Scr levels did not. To further substantiate these results, histological scores of kidneys (HSK) were evaluated. As expected, kidneys from MSC-treated rats had significantly reduced HSK compared with control PBStreated kidneys (Fig. 7E). Assessment of kidney function and structure showed that the transplantation of different MSC types, in particular MSCs CXCR4/GFP , had greater therapeutic effects than the administration of PBS alone.
Immunohistochemisty staining showed that, within kidney interstitium, CD25 or Foxp3 immunoreactivity was detected in cells interspersed among the intertitium of renal tubules. In contrast with PBS-, or MSCs shCXCR4/GFP -, or MSCs GFP -treated group, in MSCs CXCR4/GFP -treated group, more percentage of CD25 + and Foxp3 + cells were present in the different zones of

Discussion
Renal transplantation is an effective approach for end-stage renal disease. To prevent rejection reactions, organ recipients must take steroids and immune-suppressing drugs for life after surgery. However, many serious side effects of these drugs, such as infection and tumors, impact recipient survival rates and quality of life. MSCs are characterized by their low immunogenicity, abundant tissue sources, easy accessibility, and immunoregulation abilities, and therefore, they have become a good option for organ transplantation. Professor Tan has achieved good therapeutic effects in clinical treatment [41].
This study investigated the effects of CXCR4 expression modulation in MSCs on the role of MSCs in a renal transplantation model. The results showed that (i) the proportion of transplanted cells localizing into the kidneys increased with CXCR4 overexpression; and the secretory action of MSCs was critically influenced by CXCR4 gene modification. Importantly, our observations confirmed a potential role for CXCR4 in the short-term homing behavior of topically and systemically administered MSCs. We demonstrated that induced surface expression of CXCR4 by lentiviral gene transfer was able to enhance in vivo short-term homing and to enhance cell proliferation and immunosuppressive soluble factors in vitro.
Site-directed administration of MSCs is only practical for a limited number of applications, and thus, the localization of MSCs is crucial for successful therapy. Current evidence suggests that in the absence of tissue damage, systemically administered MSCs only seed the target organ at low levels [21,42], with large numbers of MSCs lodging in the pulmonary vascular bed [20][21][22][23][24][25]43,44]. The chemokine SDF-1, together with its receptor, CXCR4, plays a major role in the homing and engraftment of MSCs to target organs. Numerous studies have demonstrated that the SDF-1/CXCR4 axis is essential for MSC homing in humans and rats [45,46]. CXCR4 and SDF-1 levels are both up-regulated in stressed or injured tissues [11,[47][48][49]. Inflammation leads to activation of the endothelium, increased impermeability and the expression of various adhesion molecules. IRI-related acute inflammation causes acute organ damage and, more importantly, strengthens the host immune response by enhancing graft immunogenicity through activation of intragraft antigen-presenting cells and supporting infiltration by immune cells via up- regulation of major histocompatibility complex (MHC) class II (MHC II) antigens, intracellular adhesion molecule-1 (ICAM-1), and P-and E-selectin [50]. Therefore, IRI-induced intragraft inflammation is a key factor in renal allograft immunogenicity and explains poor outcomes [51]. MSCs, with their broad immunomodulatory and tissue-protective properties, might be ideal candidates for conditioning the environment in the recipient to combat IRI in transplanted organs [11,49]. Reports on the homing and engraftment of MSCs are limited and controversial. Recent results showed that MSCs could migrate to damaged kidneys and participate in functional and structural recovery or regeneration [52][53][54]. However, subsequent studies have demonstrated that only a few MSCs engraft injured tubules, and their overall contribution to renal repair is negligible [26,55]. Overall, in wild-type MSCs, CXCR4 expression is limited [33]. MSCs can only home and engraft into IRI kidneys to a very restricted degree. Substantial improvements are necessary to enable greater clinical benefits. CXCR4 expression is dynamic and can be regulated by cytokines, adhesion molecules, ligand-binding and proteolytic enzymes [56]. Previous studies demonstrated that such variability may be related to differences in culture conditions [30,36,57].
In the present study, we used a lentiviral system to stably overexpress or knock down a functional CXCR4 gene in rat MSCs, and we examined the effects in vivo. Based on Western blot and quantitative PCR data, as well as fluorescent microscopy, acceptable transgene expression levels were achieved. We did not determine whether other chemokines and their receptors also participated in the regulation of MSC homing in this study. However, we found that the neutralization of CXCR4 could not completely abolish MSC homing and engraftment. This finding suggests that there are other factors that affect homing, which has also been suggested by other studies [58,59]. Cooperative and compensatory mediators are involved in migration and homing, and these mediators can partially and flexibly substitute when CXCR4 expression is lost. The cytokine milieu and the source of MSCs most likely both determine the main pathway that operates in cell migration [60]. Therefore, we examined changes to cytokines in this study.
We analyzed the cytokines present in MSC cultivation supernatant and determined that many interesting changes to protein levels occurred when CXCR4 was modulated. Numerous in vitro studies have shown that MSCs have low immunogenicity [61] and poorly express or do not express HLA-I [13] or the transplantation immunity factors CD80,CD86,CD40,and CD40L [16]. In addition, MSCs have been shown to secrete cytokines and growth factors, which not only decrease IRI but also suppress immune cell functions [10,17,62]. MSCs inhibit the proliferation and cytotoxic effects of antigen-specific CTLs [63]. MSCs can also suppress T cell proliferation and activation [64]. In animal studies [65] and clinical trials [15], MSCs have been shown to exhibit immuno-depression and reduce inflammation. Their immunomodulation efficacy has also been shown in vivo during solid organ transplantation [41,66]. However, the exact MSC immunomodulatory mode of action still remains unclear. Some reports have demonstrated that the immunomodulatory properties of MSCs are associated with direct cell-cell contact with T cells [67], whereas others have shown that MSCs can regulate immune functions by secreting a variety of cytokines and chemokines, such as interleukin IL-10, nitric oxide (NO), TGF-b, PGE2, HGF, and IDO [14,17,68]. These results are compatible with our study. The up-regulation of TGF-b and IL-10 is important for the differentiation and proliferation of regulatory T cells (Treg cells) [69][70][71]. Treg cells have very important immunoregulatory effects and play a significant role in the induction of immunotolerance or the maintenance of immunosuppressive activity [72][73][74]. Furthermore, up-regulation of many factors can enhance these immunoregulatory effects of MSCs, including CCL2 [75], PGE2 [76,77],iNOS [78], VACM-1 and ICAM-1 [79], IL-4 [80], CD45 [81], and IDO [82,83]. MSCs secrete soluble factors to regulate immunity. Our findings indicate the decreased immunogenicity of transplanted kidneys and the inhibited migration of activated T cells or possibly regulatory T cells that are necessary to mediate immunomodulatory functions [8]. It is well known that IFN-a induces MHC II expression and can also be amplified by TNF-a produced by other cells [84]. ICAM-1 expression could be affected by TNF-a and IFN-c production, and it has also been reported that MSCs induce the down-regulation of ICAM-1 on co-cultured fibroblasts [85]. IL-2 and TGF-b can induce CD4 + C25 2 T cells to express Foxp3, converting them to CD4 + CD25 + Treg cells [86]. Following the down-regulation of pro-inflammatory cytokines, both MHC II expression and subsequent injurious cell migration into injured kidneys might be suppressed by the administration of MSCs.
Another unique property of MSCs is their tissue repair potential, which is attributed to their migration and differentiation capacity and their ability to secrete various growth factors [21][22][23]. Although numerous IRI-related studies describe protective effects in kidney injury or transplantation models [9,[87][88][89][90][91], few groups have focused on the relationship between changes in the paracrine action of MSCs and the induction of immunotolerance. In our study, many factors relevant to immunosuppression were upregulated when CXCR4 was overexpressed.
Analysis of the effects of MSC application within an early time frame demonstrated CXCR4-related effects on three processes: (i) the down-regulation of pro-inflammatory cytokines (TNF-a, IFNc, IL-6); (ii) the inhibition of adhesion molecules (ICAM-1), resulting in diminished infiltration by macrophages and CD3+ T cells, particularly activated CD25+ cells; and (iii) the prevention of IRI-induced release of DC-attracting chemokines (CCL19), resulting in diminished infiltration by DCs. MSCs, through direct contact [92] or through the secretion of IL-6 or PEG2, inhibit the migration abilities of DCs, enhance the conversion of DCs into immature or tolerant cell types, or affect cell activity [68,[93][94][95]. Furthermore, we found that the over-expression of CXCR4 could enhance these secretory actions. These data reveal a correlation between CXCR4 expression in MSCs and intragraft immune activation that leads to acute rejection and compromised longterm graft function. The secondary findings in our studies were the beneficial effects of CXCR4 on cell proliferation and survival, which are very important in a therapeutic context. The longer that transplanted MSCs retain their special characteristics, the more transplanted MSCs can cycle and accumulate in ischemic kidneys, and the more recipient MSCs can be incorporated among renal cells, facilitating differentiation into renal stem cells or terminal cells and ultimately participating in the repair of kidney function. MSCs form nested capillaries that might be helpful in supplying more oxygen and providing secondary protection against injury tubular [96].
Some limitations of the current study are the relatively small sample size and a failure to study the ability of MSCs to induce tolerance and long-term graft survival in our model. In our next study, we will examine whether the up-regulation of CXCR4 can also enhance the long-term residency of MSCs in transplanted kidneys. Several aspects of our study distinguish it from previous studies [97,98]. These discrepancies may be explained by differences in experimental design, such as the cell transplantation protocol, the animal strain, and the type and severity of gene mismatch.
In conclusion, we have demonstrated that MSC therapy ameliorates the negative effects of IRI in a very strong, clinically relevant model of rat kidney transplantation at early time points. CXCR4 plays a critical role not only in the process of homing but also in the pathogenesis of acute rejection and chronic allograft nephropathy, in which both immune-and non-immune-mediated mechanisms are involved. CXCR4 is a clinically useful parameter for the identification of subjects with a high risk of acute rejection, chronic allograft nephropathy, and graft failure. The pretreatment to MSCs, such as using some cytokines or anoxia to up-regulate CXCR4, may facilitate the migration of infused MSCs to the site of injury and promote tissue repair [30]. Increased CXCR4 expression can improve the homing of MSCs to transplanted kidneys, inhibit rejection reactions and accelerate the recovery of renal function in vivo. This simple method could contribute to the prevention of IRI and acute/chronic rejections and to the individualization of immunosuppressive therapies after renal transplant.

Isolation of MSCs
Two-week-old SD rats were killed by cervical dislocation. Bone marrow cells from femurs and tibiae were collected using a syringe with a 26-gauge needle, and freshly isolated cells were centrifuged at 2,000 rpm for 5 min. The marrow was washed in phosphatebuffered saline (PBS), centrifuged at 1,000 rpm for 10 min, and then re-suspended into a-modified Eagle's medium (a-MEM; GibcoH, Life Tech, USA) supplemented with 10% fetal bovine serum (FBS, Invitrogen TM ,Life Tech, USA) and 1% penicillinstreptomycin (GibcoH, Life Tech, USA) in a humidified atmosphere of 5% CO 2 at 37uC. After culture for 48 hours, nonadherent cells were removed via media replacement twice per week. When cultures reached 80-90% confluence, adherent cells were trypsinized (1% Trypsin-EDTA, GibcoH, Life Tech, USA). Cells were collected and replated at concentrations ranging between 0.05 and 0.15610 5 cells/ml of medium for several passages. MSCs from passages 4-8 were used for all experiments.

Identification and differentiation of MSCs
To confirm the identity of the isolated cells as MSCs, the expression of some surface markers was examined by flow cytometry. Surface marker expression was measured by FACS analysis using specific mouse monoclonal antibodies for the rat surface markers CD14, CD45, CD29, and CD105, followed by staining with a PE-labeled anti-mouse-IgG specific antibody (all antibodies: BD Biosciences Pharmingen, USA).

MTT and EdU Assays
To determine whether CXCR4 was involved in cellular proliferation, we infected MSCs with either a CXCR4 or shRNA-CXCR4 lentiviral vector for CXCR4 up-regulation or down-regulation, respectively. The effects of genetic regulation on MSC proliferation were measured with a 3-(4,5-dimethylthiazol-2yl)-2,5-diphenyl tetrazolium bromide assay and a 5-ethynyl-29deoxyuridine (EdU, Ruibo Biotech, China) incorporation assay using an MTT cell proliferation and cytotoxicity assay kit (Beyotime, China) and an EdU assay kit (RiboBio, China), respectively, according to the manufacturer instructions. OD values at 570 nm were measured with a Sunrise microplate reader (Tecan, Groedig, Austria). EdU-labeled cells were manually counted in ten fields of view that were randomly selected in each well, and percentages were calculated.

Viral vector construction and transduction of MSCs
The lentiviral three-plasmid expression system (kindly provided by Prof. Jian Zhang, FMMU, Xi'an, China) was used to generate the recombinant vector. A rat CXCR4 plasmid (kindly provided by Prof. ChaoJun Song, FMMU, Xi'an, China) was subcloned into the transfer vector pLV-IRES-GFP to generate the pLV-CXCR4-IRES-GFP plasmid, which contained the enhanced green fluorescence protein (eGFP) expression cassette, and insertion was confirmed by sequencing. Stable down-regulation of CXCR4 was achieved by transduction of a lentiviral vector with short hairpin RNA (shRNA) for CXCR4 (shRNA-CXCR4), generated by GenePharma (GenePharma, Shanghai, China), to knock down the expression of CXCR4. Complementary DNA oligonucleotides were then subcloned into the pLV-IRES-GFP backbone to generate the pLV-shRNA-CXCR4-IRES-GFP construct. This resulting transfer plasmid, a packaging plasmid (psPAX2), and an enveloping plasmid (pMD2.G) were co-transfected into 293T cells using Lipofectamine 2000 (Invitrogen TM , Life Tech). The cells were transfected for 6 h, and the medium was subsequently replaced. The viral particles were harvested at 48 h or 72 h after transfection, filtered through a 0.45-mm cellulose acetate filter, and concentrated by centrifugation at 50,000 rpm (4uC) for 2 h. The titer was determined via transduction of 293T cells with serial dilutions of the vector and eGFP expression assessment by flow cytometry after 72-96 h. Infection with diluted pLV resulted in less than 40% eGFP + cells, and this value was used to calculate the transducing units.

RNA preparation and RT-PCR analysis
After humanely sacrificing the animals, organs were removed and kept in liquid nitrogen until analysis. Tissues were placed in lysis buffer and then homogenized with a tissue homogenizer using TRIZOL reagent (Invitrogen TM ,Life Tech, USA), and total RNA was isolated. Total RNA was isolated from MSCs using TRIZOL reagent as well. Reverse transcription-polymerase chain reaction (RT-PCR) was performed with equal amounts of RNA using a reverse transcriptase kit (Takara, Japan) according to the manufacturer's instructions. RT was performed in a 25 ml polymerase chain reaction reaction mixture that contained 10 nM 59 and 39 oligomers and Taq DNA polymerase (Takara, Japan). Real time-PCR experiments were performed using SYBR Green (Takara, Japan) and an ABI machine. Samples were normalized based on GAPDH values. The presence and levels of CXCR4 or eGFP were determined with SYBR Premix Ex Taq kit (Takara, Japan) and a Rotor Gene 6000 Real-Time PCR Machine. The primers used for this study are available upon request. Gene sequences were searched in MEDLINE and revalidated. The temperature profile consisted of an initial step at 95uC for 10 min followed by 40 cycles of 95uC for 15 s and 60uC for 1 min. Melting curve analysis and agarose gel electrophoresis were performed after amplification. All of the results represent the average density of the positive bands obtained from three independent experiments using Quantity One software (Bio-Rad).

Western-blot analysis
Kidney samples were homogenized, and the lysates were sonicated for 10 s and centrifuged at 12,000 rpm for 15 min. Protein concentrations were determined using a bicinchoninic acid (BCA) protein assay kit (Thermo Scientific). Fifty micrograms of protein was loaded onto a 10% SDS-polyacrylamide gel, and after electrophoresis, proteins were transferred to nitrocellulose filters. The filters were blocked with TBS-T buffer containing 5% nonfat milk and were then incubated with primary anti-CXCR4 rabbit polyclonal antibodies (Santa Cruz, CA) or anti-eGFP rabbit polyclonal antibodies (Santa Cruz, CA). Equal loading of all lanes was confirmed by reprobing the membrane with anti-b-actin mouse monoclonal antibodies (Santa Cruz, CA) overnight at 4uC. Horseradish peroxidase (HRP)-conjugated secondary antibodies were obtained from Jackson ImmunoResearch Laboratories (West Grove, PA). Densitometric analysis was performed using Kodak Digital Science 1D software (Kodak, New Haven, CT). The experiments were repeated two more times with different tissues or pooled cells. The results were then statistically analyzed.

Antibody-based protein array system
Cell-free supernatants were removed from the conditioned serum-free media of 4-day cultured MSCs GFP , MSCs CXCR4/GFP , MSCs shCXCR4/GFP , or MSCs native and then analyzed with the RayBio Rat Cytokine Array V kit, which was purchased from RayBiotech (RayBio, Guangzhou, China). The array membranes can detect 90 different growth factors/cytokines at once. The layout of the membrane is depicted in Fig. 4. The assay protocol was followed precisely as stated in the directions from the manufacturer. In brief, each membrane was placed into the provided eight-well tray, 2 ml blocking buffer was added, and the membranes were incubated at room temperature for 30 min. The blocking buffer was decanted from each container, and the membranes were then incubated with 1 ml of conditioned medium at room temperature for 2 h. The samples were decanted from each container, and the membranes were washed three times with 2 ml of wash buffer I at room temperature with shaking for 5 min, followed by two washes with 2 ml of wash buffer II at room temperature with shaking for 5 min. One milliliter of 250-fold diluted biotin-conjugated antibodies was added to each membrane and incubated at room temperature for 2 h. After washing two times, 2 ml of 1000-fold diluted HRP-conjugated streptavidin was added to each membrane and incubated at room temperature for 30 min, followed again by 2 washes. The membranes were placed in detection buffer and incubated at room temperature for 5 min. Excess detection reagent was drained off, and the membrane was wrapped with PE wrap. The membrane was then exposed to Hyperfilm (Amersham Bioscience). Detectable spots were scanned by a densitometer. Positive controls, provided by the manufacturer, were normalized to 1-fold, and the densities of the unknown samples were calculated and normalized to the control spots.

ELISA
The production of SDF-1 in the kidney cortex was determined by ELISA using a commercially available ELISA kit (R&D Systems, USA) according to the manufacturer's recommendations. Tissue lysates were obtained by mincing, sonicating, and lysing with RIPA buffer. Protein content was quantified with the BCA protein assay (Thermo Scientific). All samples and standards were measured in duplicate.

Animal model of kidney transplantation
After humane animal sacrifice, kidneys from male Wistar rats were harvested, perfused with Histidine Tryptophan Ketoglutarate solution (HTK, CUSTODIOLH, Germany) to remove blood from the vascular beds and maintained at 4uC. Approximatelyone hour later, kidney grafts were transplanted into male SD recipient rats, and blood flow was restored using standard microsurgical techniques. Contralateral kidneys were removed immediately after implantation of the left kidney graft. The animals were kept in a specific pathogen-free facility with drinking water containing Cyclosporine A (CsA, 1.5 mg/kg/day, Sandimmun Neoral; Novartis) and were injected with 1 ml PBS with or without 2.0610 6 MSCs via the tail vein 24 h after the operation (n = 8 per group). Amoxicillin (1 mg/ml) was given each day to prevent infection. Three days after transplantation, the rats were euthanized, and grafts and some original organs were harvested for Western blot, RT-PCR and histological analysis (n = 8 per group). Operated animals appeared healthy until just before graft harvest without surgical complications during the observation period.

Cell transplantation procedures
To mimic the stem cell transplant protocol utilized in clinical renal transplant patients, SD recipient rats received lentiviraltransduced MSCs or native MSCs (2610 6 ) diluted in 1 ml PBS or 1 ml PBS alone as a control via straight perfusion and caudal vein injections. Straight perfusions were performed when draining blood from donor kidneys, and injections were performed 24 h after renal transplants.

Histopathological and biochemical analysis
To assess the therapeutic effects of native and genetically engineered MSC populations, blood was harvested 12 h and 72 h after renal transplantation, and tissue samples were harvested 72 h after transplantation. Biochemical and histopathological analyses were then performed (n = 8 per group). Briefly, random fields were analyzed using a 406 objective. The excised kidneys were fixed in phosphate-buffered 10% formalin, sectioned, and then stained with hematoxylin and eosin. HSK evaluation was performed in a blind manner by two separate pathologists. HSK was graded on a 4-point scale [99]: 0 = normal histology; 1 = mild damage [less than one-third of nuclear loss (necrosis) per tubular cross section]; 2 = moderate damage [greater than one-third and less than twothirds of tubular cross section showing nuclear loss (necrosis)]; and 3 = severe damage [greater than two-thirds of tubular cross section shows nuclear loss (necrosis)]. The total score per kidney section was calculated by adding all 10 scores with a maximum possible injury score of 30. Quantification of Scr in serum samples was performed via an enzymatic method on a Cobas Integra analyzer (Roche, Indianapolis, IN). BUN quantification was performed manually via the diacetyl monoxime method.

Immunohistochemical staining
To assess CD25, FOXP3, and CD45 expression in transplanted kidneys of four groups and normal renal tissues (Paraffinembedded sections), The Paraffin-embedded sections were fixed in freshly prepared 10% paraformaldehyde for 5 min. After blocking the endogenous peroxidase activity with 0.3% hydrogen peroxide in TBS for 15 min, the serial sections (5-mm thick) were immersed in horse serum diluted 1:10 in TBS for 30 min to reduce nonspecific binding, and then were incubated with antibodies against CD25, or FOXP3, or CD45 (Abcam, diluted 1 : 100,United States) overnight at after washing in TBS. Next, the sections were incubated in biotinylated IgG for 30 min, and avidin-biotin-peroxidase complex for 30 min. After each step of the staining procedure, the sections were given three 5-min washes in TBS. Immunoreactivity (IR) was visualized using 1 mg/mL diaminobenzidine as chromogen and 0.01% hydrogen peroxide as substrate. The peroxidase reaction was stopped after 5 min with distilled water, and the sections were counter-stained with Toluidine blue, dehydrated, and then mounted with Entellan. Slides were evaluated under a light microscope (original magni-fication2006). For digital image analysis, the software Imagepro-Plus was used. Results were scored by two independent investigators as hadro-positive (+++), positive (++), weakly positive (+), heterogeneous (+2), or negative (2). The two scores were averaged.

Fluorescence microscopy for analysis of eGFP-positive cells
To determine whether overexpression of CXCR4 enhances the chemotaxis of MSCs into transplanted kidneys, the presence of eGFP was used to distinguish resident MSCs from injected MSCs. For the in vivo migration assay with donor MSCs, the kidneys of euthanized rats were removed 3 days after transplantation, as previously described, and cryosectioned into 6-mm sections. The sections were observed under a fluorescence microscope (Olympus) to identify eGFP + MSCs. Ten random fields were analyzed using a 406 objective. The number of labeled MSCs per visual field was estimated by Image J software.

Statistical analysis
The results were statistically analyzed using SigmaStat (SPSS) version 11.0 software. All of the values were expressed as the mean 6 SD. A one-way analysis of variance (ANOVA) or paired t-test was used for multiple or two-group comparisons. All of the tests were two-tailed, and a p-value of ,0.05 was considered statistically significant.