Allochimeric molecules and mechanisms in abrogation of cardiac allograft rejection

The significant role of the Golgi apparatus in cardiovascular diseases

The Golgi apparatus (GA) is a ribbon-like system of stacks which consist of multiple closely apposed flattened cisternae and vesicles usually localized in the juxta-nuclear area. As for the biological functions, the GA plays a major role in protein biosynthesis, post-translational modification, and sorting protein from ER to plasma membrane and other destinations. Structural changes and functional disorder of the GA is associated with various diseases. Moreover, increasing evidence revealed that swelling, poor development, and other morphological alterations of the GA are linked to cardiovascular diseases such as heart failure (HF), arrhythmia, and dilated cardiomyopathy. Furthermore, dysfunction of the GA is also related to cardiovascular diseases since the GA is extremely responsible for transport, glycosylation, biosynthesis, and subcellular distribution of cardiovascular proteins. This review gives a brief overview of the intricate relationship between the GA and cardiovascular diseases. In addition, we provide a further prospective that the GA may provide diagnosis reference for cardiovascular diseases, and changes in the ultrastructure and morphology of the GA such as swelling, poor development, and fragmentation may serve as a reliable index for cardiovascular diseases.

Abrogation of chronic rejection in rat model system involves modulation of the mTORC1 and mTORC2 pathways

BACKGROUND

Current immunosuppressive regimens fail to avert chronic rejection (CR) of transplanted organs; however, selective targeting of actin-cytoskeletal regulators decreases T-cell motility and abrogates CR in rat model system. Administration of mutated class I major histocompatibility complex molecules or selective targeting of the RhoA pathway, which controls T-cell cytoskeletal activity, using Y27632 (a selective Rock1 inhibitor) resulted in reduced T-cell infiltration and abrogation of CR as judged from the neointimal index (13.9±19.7 vs. 45±37.5; P<0.001) and the number of affected vessels (30% vs. 60%; P<0.01). Here, we examined the role of mammalian target of rapamycin (mTOR) pathway in inhibition of CR.

METHODS

A mutated class I major histocompatibility complex molecule that eliminates CR was delivered into ACI recipients of Wistar-Furth hearts at the time of transplantation with subtherapeutic cyclosporine (10 mg/kg on days 0-2). Controls included untreated and cyclosporine A-treated (10 mg/kg on days 0-2) heart allograft recipients.

RESULTS

Western blotting and immunostaining showed that rat heart allografts with abolished CR exhibited down-regulation of the RAPA-sensitive mTORC1 components such as mTOR and Raptor and down-regulation of the RAPA-insensitive mTORC2 elements Rictor and Sin1. The mTOR regulator Deptor and its downstream target Rac1 were also inhibited.

CONCLUSIONS

Abrogation of CR in rat model system involves modulation of two mTOR pathways: a RAPA-sensitive mTORC1 pathway regulating cellular proliferation and a RAPA-insensitive mTORC2 pathway regulating T-cell motility. Selective targeting of T-cell actin cytoskeletal pathways shows potential for pathway-targeted immunosuppression therapies.

Sumoylation of human translationally controlled tumor protein is important for its nuclear transport

Translationally controlled tumor protein (TCTP) lacks nuclear bipartite localization signal sequence; yet TCTP is present abundantly in the nucleus. At present it is not known how TCTP gets transported to the nucleus. Sequence analyses showed that all TCTPs described to date have putative small ubiquitin-like modifier (SUMO) motifs. Since SUMO modification plays an important role in the nuclear transport of proteins, we evaluated whether SUMO motifs are important for transport of TCTP into the nucleus. We show that TCTP exists in sumoylated form in cytoplasm and nucleus of mammalian cells. Point mutation of lysine residue in the SUMO motif compromised the ability of TCTP to get sumoylated in vitro. When cells were transfected with FLAG-tagged mutated TCTP, nuclear transport of TCTP was inhibited confirming that sumoylation is critical for the nuclear transport of TCTP. Our previous studies demonstrated that TCTP can function as an antioxidant protein in the nucleus. When we mutated TCTP at the SUMO motif the antioxidant function of TCTP was compromised. Results presented in this study thus show that sumoylation plays an important role in the transport of TCTP into the nucleus where they function as antioxidant protein.