Germline deletion of AMP-activated protein kinase beta subunits reduces bone mass without altering osteoclast differentiation or function.

Since AMP-activated protein kinase (AMPK) plays important roles in modulating metabolism in response to diet and exercise, both of which influence bone mass, we examined the influence of AMPK on bone mass in mice. AMPK is an alphabetagamma heterotrimer where the beta subunit anchors the alpha catalytic and gamma regulatory subunits. Germline deletion of either AMPK beta1 or beta2 subunit isoforms resulted in reduced trabecular bone density and mass, but without effects on osteoclast (OC) or osteoblast (OB) numbers, as compared to wild-type littermate controls. We tested whether activating AMPK in vivo would enhance bone density but found AICA-riboside treatment caused a profound loss of trabecular bone volume (49.5%) and density and associated increased OC numbers. Consistent with this, AICA-riboside strongly stimulated OC differentiation in vitro, in an adenosine kinase-dependent manner. OCs and macrophages (unlike OBs) lacked AMPK beta2 subunit expression, and when generated from AMPK beta1(-/-) mice displayed no detectable AMPK activity. Nevertheless, AICA-riboside was equally effective at stimulating OC differentiation from wild-type or beta1(-/-) progenitors, indicating that AMPK is not essential for OC differentiation or the stimulatory action of AICA-riboside. These results show that AMPK is required to maintain normal bone density, but not through bone cell differentiation, and does not mediate powerful osteolytic effects of AICA-riboside.

AMP-activated protein kinase, super metabolic regulator.

The AMP-activated protein kinase (AMPK) is a metabolic-stress-sensing protein kinase that regulates metabolism in response to energy demand and supply by directly phosphorylating rate-limiting enzymes in metabolic pathways as well as controlling gene expression.

Identification of immunodominant donor MHC peptides following rejection and donor strain transfusion-induced tolerance of heart allografts in adult rats.

Pre-graft priming of heart allograft recipients with donor strain blood induces tolerance in 100% of adult rats in the congenic LEW.1W to LEW.1A combination. This tolerant state is specific for donor MHC antigens as third-party blood transfusions fail to induce tolerance, and third-party skin grafts are promptly rejected by tolerant graft recipients. In this study we have characterized the immunodominant donor (RT1u) class I and II allogenic peptides which elicit an in vitro proliferative response to splenocytes from recipients (RT1a) undergoing acute rejection or tolerant to a LEW.1A cardiac allograft. Paradoxically, splenocytes from tolerant animals responded more vigorously to a broader set of donor peptides than splenocytes from rejecting animals. In addition, several of these peptides were observed to be stimulatory only for tolerant splenocytes. These findings suggest that regulatory cells may be involved in tolerance induction or maintenance and are selected by specific motifs, which could be utilized for manipulating the immune system of graft recipients.

Combination of decay-accelerating factor expression and alpha1,3-galactosyltransferase knockout affords added protection from human complement-mediated injury.

BACKGROUND: Hyperacute rejection (HAR) currently prevents the use of pigs as organ donors for humans. It is now generally accepted that the key instigators of HAR are naturally occurring xenoantibodies against the terminal disaccharide galactose alpha1,3-galactose (Gal), and the species incompatibility between human complement and porcine complement regulatory molecules. Using two in vitro models and an ex vivo mouse heart perfusion model, we have shown previously that cells and tissues from Gal knockout (Gal KO) and transgenic mice expressing the human cell surface complement regulator decay-accelerating factor (DAF/CD55) are partially, but not completely, protected from human complement-mediated injury. METHODS: In the present study, Gal KO mice were crossed with DAF transgenic mice and bred to homozygosity (DAF/Gal KO). Isolated splenocytes were incubated with human serum, and the protective effect of DAF and Gal KO was assessed by measuring complement deposition and cell lysis. Hearts perfused ex vivo with human plasma were examined for human antibody and complement deposition, and assessed functionally by measuring work performed by the heart. RESULTS: Splenocytes from DAF/Gal KO mice were found to be more resistant to complement-mediated injury than cells from either DAF transgenic or Gal KO mice. In addition, hearts from DAF/Gal KO mice, when perfused with human plasma, displayed prolonged survival compared with hearts from Gal KO mice. This was associated with a reduction in the extent of endothelial deposition of IgG, IgM, and complement C3b. CONCLUSIONS: These findings demonstrate that expression of human DAF in association with elimination of the Gal epitope provides added protection from complement-mediated injury in these models of HAR.

Expression of functional decay-accelerating factor (CD55) in transgenic mice protects against human complement-mediated attack.

Transgenic mice expressing human CD55 were generated by microinjection of a CD55-minigene under the control of the mouse H2K(b) (MHC class I) promoter. Offspring were tested for transgene integration by PCR analysis, and for CD55 expression on peripheral blood leukocytes (PBLs) by flow cytometry. Expression levels of 15 founders ranged from 30 to 80% of that on human neutrophils. Immunohistochemical analysis of kidney, heart, liver, and lung tissue demonstrated staining for CD55 on endothelial surfaces as well as general diffuse staining throughout the tissues. The capacity of the transgenically expressed CD55 to prevent human C3 deposition on the surface of mouse splenocytes was assessed by flow cytometry. Cells from hemizygous mice incubated with 10% fresh human serum as a source of natural antibody and complement bound approximately 65% less C3 than control littermates. No further protection was seen using cells from homozygous littermates, and the protective effect was abrogated by prior incubation with an OFFi-CD55 monoclonal antibody. Similarly, transgenic mice were afforded significant protection from human serum-mediated lysis, determined using an LDH release assay. Hearts perfused with human plasma showed no increase in survival time in a modified Langendorff perfusion system, however deposition of human C3c was greatly reduced in transgenic hearts.

The alpha-1,3-galactosyltransferase knockout mouse. Implications for xenotransplantation.

Organ xenografts in discordant combinations such as pig-to-man undergo hyperacute rejection due to the presence of naturally occurring human anti-pig xenoantibodies. The galactose alpha(1,3)-galactose epitope on glycolipids and glycoproteins is the major porcine xenoantigen recognized by these xenoantibodies. This epitope is formed by alpha(1,3)-galactosyltransferase, which is present in all mammals except man, apes, and Old World monkeys. We have generated mice lacking this major xenoantigen by inactivating the alpha(1,3)-galactosyltransferase gene. These mice are viable and have normal organs but develop cataracts. Substantially less xenoantibody from human serum binds to cells and tissues of these mice compared with normal mice. Similarly, there is less activation of human complement on cells from mice lacking the galactose alpha(1,3)-galactose epitope. These mice confirm the importance of the galactose alpha(1,3)-galactose epitope in human xenoreactivity and the logic of continuing efforts to generate pigs that lack this epitope as a source of donor organs.