Yang-Sun Jin

EMAP II: a modulator of neovascularization in the developing lung

Neovascularization is a key regulatory process in fetal growth and development. Although factors promoting growth and development of the pulmonary vasculature have been investigated, nothing is known regarding the molecular mechanisms that may counteract these stimuli. Endothelial monocyte-activating polypeptide (EMAP) II has recently been identified as an antiangiogenic factor in tumor vascular development. We postulated that EMAP II is a putative negative modulator of lung vascular growth. EMAP II mRNA and protein decrease fivefold (P < 0.01) as the developing lungs in the fetal mouse progress from having poor vascularization (day 14) to having complete vascular development at term (day 18.5). EMAP II protein expression continues to remain low throughout postnatal life and into adulthood, with the exception of a surge that correlates with microvascular maturation. Furthermore, through the use of in situ hybridization and immunohistochemistry, EMAP II is localized throughout the lung, with significant expression in the submyoepithelial area during the early stages of lung development when there is minimal vascular development. In contrast, EMAP II is distributed around the large vessels during the end of vascular development, suggesting that EMAP II modulates the neovascularization process. We speculate that EMAP II is a director of neovascularization in the developing lung.Neovascularization is a key regulatory process in fetal growth and development. Although factors promoting growth and development of the pulmonary vasculature have been investigated, nothing is known regarding the molecular mechanisms that may counteract these stimuli. Endothelial monocyte-activating polypeptide (EMAP) II has recently been identified as an antiangiogenic factor in tumor vascular development. We postulated that EMAP II is a putative negative modulator of lung vascular growth. EMAP II mRNA and protein decrease fivefold ( P < 0.01) as the developing lungs in the fetal mouse progress from having poor vascularization ( day 14) to having complete vascular development at term ( day 18.5). EMAP II protein expression continues to remain low throughout postnatal life and into adulthood, with the exception of a surge that correlates with microvascular maturation. Furthermore, through the use of in situ hybridization and immunohistochemistry, EMAP II is localized throughout the lung, with significant expression in the submyoepithelial area during the early stages of lung development when there is minimal vascular development. In contrast, EMAP II is distributed around the large vessels during the end of vascular development, suggesting that EMAP II modulates the neovascularization process. We speculate that EMAP II is a director of neovascularization in the developing lung.

Evidence for recipient derived fibroblast recruitment and activation during the development of chronic cardiac allograft rejection.

Background. Allograft fibrosis is a prominent feature of chronic rejection. Although intragraft fibroblasts contribute to this process, their origin and exact role remain poorly understood. Methods. Using a rat model of chronic rejection, LEW to F344, cardiac fibroblasts were isolated at the point of rejection and examined in a collagen gel contraction assay to measure fibroblast activation. The allograft microenvironment was examined using immunohistochemistry for fibrogenic markers (transforming growth factor [TGF]-&bgr;, platelet-derived growth factor [PDGF], tissue plasminogen activator [TPA], plasminogen activator inhibitor [PAI]-1, matrix metalloproteinase [MMP]-2, and tissue inhibitor of matrix metalloproteinase [TIMP]-2). The origin of intragraft fibroblasts was studied using female to male allografts followed by polymerase chain reaction [PCR] and in situ hybridization for the male sry gene. Results. The cardiac fibroblasts isolated from allografts with chronic rejection exhibited higher gel contractibility (50.9% ± 6.1% and 68.2% ± 3.8% at 4 and 24 hr) compared with naive cardiac fibroblasts (30.7% ± 3.5% and 55.3% ± 6.6% at 4 and 24 hr; P <0.05 and <0.05, respectively). Immunostaining for TGF-&bgr;, PDGF, TPA, PAI-1, MMP-2 and TIMP-2 was observed in all allografts at the time of rejection. In situ hybridization demonstrated the presence of sry positive cells in female allografts rejected by male recipients. Sixty-five percent of fibroblast colonies (55 of 85) isolated from female heart allografts expressed the male sry gene. Conclusion. Cardiac fibroblasts are activated and exist in a profibrogenic microenvironment in allografts undergoing chronic rejection. A substantial proportion of intragraft fibroblasts are recruited from allograft recipients in this experimental model of chronic cardiac allograft rejection.

Identification, functional analysis and expression in a heterotopic heart transplant model of CXCL9 in the rat

CXCR3 chemokines are of particular interest because of their potential involvement in a variety of inflammatory diseases, including the rejection of organ transplants. Although the rat is one of the most appropriate animals for using to study transplantation biology, the structural and functional characteristics of CXCL9 [monokine induced by interferon‐γ (Mig)] in this experimental model have not been described. Therefore, we recently conducted a series of experiments to identify and characterize the rat CXCL9 gene. Accordingly, we isolated rat CXCL9 cDNA and genomic DNA. The rat CXCL9 gene encodes a protein of 125 amino acids and spans a 3·5 kbp DNA segment containing four exons in the protein‐coding region. We then analysed mRNA expression in various tissues. Transcripts for the gene were found to be expressed at high levels in the lymph nodes and spleen. Then, to confirm the function of the identified gene, rat CXCL9 was transiently expressed in COS‐1 cells. Rat recombinant Mig displayed chemotactic properties and induced CXCR3 internalization in CD4+ T cells. Lastly, we analysed the expression of rat CXCL9 in a heterotopic heart allograft model. Both mRNA and protein levels of intragraft CXCL9 were significantly increased following transplantation of ACI to LEW hearts when compared with syngeneic controls. These findings indicate that rat CXCL9 has an in vivo role in the infiltration of CD4+ T cells in the transplanted graft.

Maturation of xenoantibody gene expression during the humoral immune response of rats to hamster xenografts.

Abstract: Immunoglobulin isotype switching represents an important component of antibody maturation in the development of humoral immune responses. We have recently conducted a series of studies in a nonimmunosuppressed rodent model to define the kinetics of xenoantibody production and seek evidence for the maturation of xenoantibody Ig gene expression by xenograft recipients. LEW rats were transplanted with hamster cardiac xenografts and the grafts were allowed to remain in situ for prolonged immune stimulation of the host. Anti‐hamster antibodies were examined at days 4, 8, 21, 28 and 40 post‐transplantation. cDNA libraries specific for rat µ or γ heavy chains were constructed from B lymphocytes of the xenograft recipients at day 4 and day 21 post‐transplantation. Selected cDNA clones encoding the Ig VHHAR family of genes from each group were sequenced and analyzed for the presence of somatic mutations. We found that the reactivity of xenoantibodies examined with flow cytometry underwent sequential changes in which IgM titers peaked at day 8 post‐transplantation (PTx) and returned to low levels after 21 days. IgG titers started to increase at about one week PTx and peaked at 21–28 days. All the IgG isotypes (IgG1, 2a, 2b and 2c) were differentially involved in the IgG responses. Serum passive transfer experiments demonstrated that IgM antibody fractions separated from sera at day 4 post‐transplantation were capable of causing hyperacute rejection (HAR) of hamster xenografts, whereas IgM fractions from days 21–40 failed to cause HAR (N = 7, MST = 4 days), a pattern that was consistent with a rise in total xenoreactive IgM levels at days 4–8 and a fall to low levels at 21 days post‐transplantation. IgG‐containing fractions separated from day 21–40 antisera caused HAR (N = 7, MST = 36 min) whereas IgG fractions from day 8 sera failed to induce graft rejection. Genetic analysis of the rearranged VH genes from 10 cDNA clones demonstrated that the Ig µ (n = 5) and γ (n = 5) chain clones used the same family of VH genes (VHHAR family) to encode their antibody binding activity. The majority (80%) of the IgM clones were present in their original germline configuration. In contrast, the nucleotide sequences from IgG clones manifested an increase in the numbers of replacement mutations in the CDR region of the Ig heavy chain genes, providing evidence for a potential role for somatic mutation in the maturation of IgG xenoantibody responses as the humoral response matures with time post‐transplantation.