Mohammed Awad

Genotypic variation in the transforming growth factor-β1 gene : Association with transforming growth factor-β1 production, fibrotic lung disease, and graft fibrosis after lung transplantation

BACKGROUND Transforming growth factor (TGF)-beta1 is a profibrogenetic cytokine that has been implicated in the development of fibrosis in transplanted tissues. In this study, we have analyzed the genetic regulation of TGF-beta1 production in lung transplant recipients. METHOD A polymerase chain reaction-single-stranded conformational polymorphism technique was used to detect polymorphisms in the TGF-beta1 gene from genomic DNA. Polymorphisms were shown to correlate with in vitro TGF-beta1 production by stimulated lymphocytes. A single-specific oligonucleotide probe hybridization method was devised to screen for these polymorphisms in lung transplant groups and controls. RESULTS We have identified five polymorphisms in the TGF-beta1 gene: two in the promoter region at positions -800 and -509, one at position +72 in a nontranslated region, and two in the signal sequence at positions +869 and +915. The polymorphism at position +915 in the signal sequence, which changes codon 25 (arginine-->proline), is associated with interindividual variation in levels of TGF-beta1 production. Stimulated lymphocytes of homozygous genotype (arginine/arginine) from control individuals produced significantly more TGF-beta1 in vitro (10037+/-745 pg/ml) compared with heterozygous (arginine/proline) individuals (6729+/-883 pg/ml; P<0.02). In patients requiring lung transplantation for a fibrotic lung condition, there was an increase in the frequency of the high-producer TGF-beta1 allele (arginine). This allele was significantly associated with pretransplant fibrotic pathology (P<0.02) (n=45) when compared with controls (n=107) and with pretransplant nonfibrotic pathology (P<0.004) (n=50). This allele was also associated with allograft fibrosis in transbronchial biopsies when compared with controls (P<0.03) and with nonallograft fibrosis (P<0.01). CONCLUSION The production of TGF-beta1 is under genetic control, and this in turn influences the development of lung fibrosis. Hence, the TGF-beta1 genotype has prognostic significance in transplant recipients.

CA repeat allele polymorphism in the first intron of the human interferon-gamma gene is associated with lung allograft fibrosis.

Interferon-gamma (IFN-gamma) is an inflammatory cytokine that has been implicated in the development of fibrosis in inflamed tissues. In this study we have analysed the association between genetically-determined high IFN-gamma production and development of fibrosis in lung transplants. The human IFN-gamma gene has a variable length CA repeat in the first intron. Our previous study showed that polymorphism of this microsatellite is associated with individual variation in the levels of IFN-gamma production. In vitro production of IFN-gamma showed significant correlation with presence of allele #2 (p < 0.01). In this study allele #2 was found to be associated with allograft fibrosis defined by transbronchial biopsy. An analysis of two groups of lung transplant recipients showed a significant increase in the frequency of allele #2 in the group which developed fibrosis after transplantation compared to the group that did not (p < 0.005). We postulate that the production of IFN-gamma, which is under genetic control, can influence the development of fibrosis in lung allografts.

Transforming growth factor-beta (TGF-β1) genotype and lung allograft fibrosis

BACKGROUND TGF-beta1 is a prosclerotic cytokine implicated in fibrotic processes. Fibrosis of the pulmonary parenchyma and airways is a frequent presentation in lung transplant recipients before and after transplantation. There are two genetic polymorphisms in the DNA sequence encoding the leader sequence of the TGF-beta1 protein, located at codon 10 (either leucine or proline) and at codon 25 (either arginine or proline). The codon 25 arginine allele is associated with higher TGF-beta1 production by cells activated in vitro. We tested the hypothesis that inheritance of alleles of the TGF-beta1 gene conferring higher production of TGF-beta1 may be responsible for over-expression of TGF-beta1 in transplant recipients resulting in lung allograft fibrosis. METHODS We extracted DNA from leukocytes collected from 91 pulmonary transplants performed at our centre and 96 normal healthy volunteers between May 1990 and September 1995. Part of the first exon was amplified by PCR. Samples were genotyped by using sequence specific oligonucleotide probes. RESULT The distribution of codon 10 alleles was similar in a normal healthy control group and in lung transplant recipients, regardless of their pretransplant lung pathology. By contrast, there was a significant difference in the frequency of codon 25 alleles between the control and transplant groups. In the normal control group 81% were codon 25 arginine/arginine (A/A) homozygotes, 19% were arginine/proline (A/P) heterozygotes and none were proline/proline (P/P) homozygotes. The distribution of codon 25 alleles was similar in lung transplant recipients who did not have a significant fibrosis in pretransplant pathology, but in transplant recipients who came to transplantation with lung fibrosis 98% (41 of 42 patients) were homozygous for the codon 25 A/A allele (p < .05). After lung transplantation 39 of 91 patients developed lung allograft fibrosis, and of these 92.3% (36 of 39 recipients) were of homozygous codon 25 A/A high TGF-beta1 producer genotype (p < .001). Lung transplant recipients who were homozygous for both codon 10 L/L and codon 25 A/A showed poor survival compared with all other TGF-beta1 genotypes (p < .03). CONCLUSION Homozygosity for arginine at codon 25 of the leader sequence of TGF-beta1 that correlates with higher TGF-b production in vitro, is associated with fibrotic lung pathology before lung transplantation and with the development of fibrosis in the graft. In combination with the codon 10 leucine allele, homozygosity for the codon 25arginine allele is a marker for poor post-transplant prognosis and recipient survival.

Transforming growth factor-β1 and lung allograft fibrosis

OBJECTIVES: Transforming growth factor beta1 (TGF-beta1) is a potent immunosuppressive cytokine that promotes fibrosis by enhancing the synthesis of extracellular matrix components. The repair process following lung allograft injury is due to rejection or infection replaces lung parenchyma by fibrotic tissue, leading to pulmonary dysfunction. The role of TGF-beta1 in this excessive healing process and increasing the risk of infection is unknown. METHODS: We analysed our patient data to investigate the relevance of different factors on allograft fibrosis and its correlation with TGF-beta1. Fibrosis was graded in H and E stained sections. TGF-beta1 genotype was determined in all patients. RESULTS: Patients were aged between 16 and 62 years (mean age of 39.6 years). Procedures were heart/lung (n = 32), double lung (n = 18), and SLT (n = 41). A total of 46 patients had lung allograft fibrosis diagnosed in transbronchial biopsies sections. Patients who had developed interstitial fibrosis had significantly more acute rejection episodes (mean 3.4 +/- 2.8) compared with patients without fibrosis (mean 2.1 +/- 2.2) (P = 0.024). The presence of eosinophils in the interstitium preceded and were associated with the development of fibrosis regardless of the rejection grade (P = 0.0001). TGF-beta1 was heavily expressed in sections with fibrosis with a mean score of 6.8 +/- 2.9 compared with 2.4 +/- 0.6 in sections with no fibrosis (P 6 is 892.4 +/- 73 days compared with mean survival 427 +/- 78 in patients with scores < 6 (P = 0.0001). Patients who developed fibrosis had homozygous TGF-beta1 genotype that correlates with excessive TGF-beta1 expression (P = 0.01). The use of cardiopulmonary bypass was associated with the development of excessive fibrosis (P = 0.02), and 7 patients who had severe fibrosis died of septicaemia (17.5%). FEV1 (forced expiratory volume) was significantly higher in patients without fibrosis (1870 +/- 111 ml versus 1590 +/- 160; P = 0.02). CONCLUSIONS: The risks of lung allograft fibrosis increases with recurrent rejection, tissue eosinophilia, homozygous TGF-beta1 genotype and the use of bypass machine. Fibrosis was associated with higher mortality and morbidity might be explained by the TGF-beta1 immunosuppressive and fibrotic properties. Immunological strategies to down-regulate TGF-beta1 production might improve survival and function of lung allografts.

Neutrophils and lymphoid chimerism after adult living-related liver transplantation from a homozygous donor

Chimerism and graft-versus-host disease (GVHD) pose significant risks to liver transplant patients. The risk of chimerism and GVHD is higher among cases of living-related liver transplant (LRLT). Donors homozygous at all HLA loci carry a higher risk for GVHD. Herein we present a case of LRLT. The recipient suffered from end-stage liver disease and received a right lobe graft from his son. After 8 months posttransplant, the patient developed profound bone marrow depression. The patient was negative for CMV, Brucella, HHV6, HHV8, HBV, HCV, and parvovirus. No skin or GI signs of GVHD were noted. The patient and donor were HLA typed by SSP. The donor was homozygous for all HLA loci while the patient shared the class II homozygosity and was class I heterozygous. Chimerism studies were prompted after noting that the neutrophil compartment of the patient was homozygous for all HLA loci. This initiated further studies of the PMN and lymphocytes by microsatellite analysis. A total 15 microsatellites were analyzed. The results suggest that the majority (75%) of the PMNs and 45% of the lymphocytes were of donor origin. The patient was treated with G-CSF; his WBC counts returned to normal. At 2.5 years posttransplant the patient had not developed GVHD, despite the large number of donor lymphocytes circulating in his bloodstream. The only complaint he had was severe arthritis, which was treated with steroids. It must be investigated whether this was the result of GVHD.