Antibody-mediated rejection--an ounce of prevention is worth a pound of cure.

The presence of preformed, donor-specific alloantibodies inpatients undergoing renal transplantation is associated with a high risk of hyperacute and acute antibody-mediated rejection (ABMR), and often limits potential recipients' access to organs from living and deceased donors. Over the last decade, understanding of ABMR has improved markedly and given rise to numerous, diverse strategies for the transplantation of allosensitized recipients. Antibody desensitization programs have been developed to allow renal transplant recipients with a willing but antibody-incompatible living donor to undergo successful transplantation, whereas kidney paired exchange schemes circumvent the antibody incompatibility altogether by finding suitable pairs to donors and recipients. Recognizing the complexity of ABMR and the recent developments that have occurred in this important clinical research field, the Roche Organ Transplantation Research Foundation (ROTRF) organized a symposium during the XXIII Congress of The Transplantation Society in Vancouver, Canada, to discuss current understanding in ABMR and ways to prevent it. This Meeting Report summarizes the presentations of the symposium, which addressed key areas that included the interactions between alloantibodies and the complement system in mediating graft injury, technological advancements for assessing antibody-mediated immune responses to HLA antigens, and the potential benefits and challenges of desensitization and kidney paired donation schemes.

The long form of CDK2 arises via alternative splicing and forms an active protein kinase with cyclins A and E.

We have reinvestigated the long form of cyclin-dependent kinase (CDK)2 that is expressed in many rodent cells. We show that the mRNA encoding CDK2L arises by alternative splicing and that the encoded protein can bind to, and be activated by, cyclins A and E. The complex of CDK2L with cyclin A has about half the specific activity of the equivalent CDK2-cyclin A complex. Also, CDK2L--cyclin A is inhibited to the same extent and by the same concentrations of p21(CIP1) as CDK2--cyclin A. The nucleotide sequences of intron V in the human and murine CDK2 genes, where the sequences encoding the 48-residue insert in CDK2L are located, show very high conservation in the position of the alternatively spliced exon and its surroundings. Despite this, we were not able to detect significant expression of CDK2L in human cell lines, although a low level is expressed in COS-1 cells from monkeys.