Measuring Disparate Impacts and Extending Disparate Impact Doctrine to Organ Transplantation

This paper examines the economic and statistical foundations of proposed tests for discrimination. We focus on extension of disparate impact doctrine to new domains.

Transverse Cerebellar Diameter On Cranial Ultrasound Scan In Preterm Neonates In An Australian Population

Objective: Fetal measurement of transverse cerebellar diameter (TCD) has been shown to correlate well with gestational age (GA), even in the presence of growth retardation. The aim of this study was to define the normal range of TCD in preterm neonates in an Australian population between 23 and 32 weeks GA. Methodology: Infants admitted to the Royal Women's Hospital, Melbourne, having routine cranial ultrasound scans (< 1500 g and/or of gestational age 32 weeks at birth) had their TCD measured on a cranial scan performed during the first 3 days of life. The posterior fossa was examined through the asterion using a General Electric LOGIQ 500 scanner (GE Medical Systems, Waukesha, USA) and TCD measurement was taken in the coronal plane. Results: 106 infants < 1500 g and/or of GA 32 weeks at birth had their TCD measured between 1 January 1997 and 30 November 1997. Transverse cerebellar diameter and associated 95% confidence intervals are described for infants between 23 and 32 weeks GA. The linear regression equation relating TCD and GA was: TCD (mm) = 12.9 + 1.61 GA (weeks). R2 = 0.80, P< 0.001. Conclusion: This is the only study of TCD measurement using cranial ultrasound in a group of preterm newborns, and forms the basis for nomograms of TCD which can be used as a tool to assist in the assessment of GA, even in growth-retarded preterm newborns, and in the diagnosis of cerebellar hypoplasia

A monoclonal antibody raised against a thermo-stabilised β1-adrenoceptor interacts with extracellular loop 2 and acts as a negative allosteric modulator of a sub-set of 1- adrenoceptors expressed in stable cell lines

Recent interest has focused on antibodies that can discriminate between different receptor conformations. Here we have characterised the effect of a monoclonal antibody (mAb3), raised against a purified thermo-stabilised turkey β1-adrenoceptor (β1AR-m23 StaR), on β1-ARs expressed in CHO-K1 or HEK 293 cells. Immunohistochemical and radioligand-binding studies demonstrated that mAb3 was able to bind to ECL2 of the tβ1-AR, but not its human homologue. Specific binding of mAb3 to tβ1-AR was inhibited by a peptide based on the turkey, but not the human, ECL2 sequence. Studies with [3H]-CGP 12177 demonstrated that mAb3 prevented the binding of orthosteric ligands to a subset (circa 40%) of turkey 1-receptors expressed in both CHO K1 and HEK 293 cells. MAb3 significantly reduced the maximum specific binding capacity of [3H]-CGP-12177 without influencing its binding affinity. Substitution of ECL2 of tβ1-AR with its human equivalent, or mutation of residues D186S, P187D, Q188E prevented the inhibition of [3H]-CGP 12177 binding by mAb3. MAb3 also elicited a negative allosteric effect on agonist-stimulated cAMP responses. The identity of the subset of turkey β1-adrenoceptors influenced by mAb3 remains to be established but mAb3 should become an important tool to investigate the nature of β1-AR conformational states and oligomeric complexes

Diagnostic and therapeutic aspects of β1-adrenergic receptor autoantibodies in human heart disease

AbstractGrowing evidence indicates a cardio-pathogenic role of autoantibodies against β1-adrenergic receptors (β1AR). In particular autoantibodies stimulating β1AR-mediated cAMP-production (i.e. agonistic β1AR autoantibodies) play a paramount role in chronic heart failure. When induced by immunisation, such autoantibodies cause heart failure in rodents; when present in patients they negatively affect survival in heart failure. However, the true prevalence and clinical impact of agonistic β1AR autoantibodies in human heart disease are still unclear, as are the events triggering their production, and the inter-relationship between autoantibody level and disease activity. β1AR autoantibodies can be removed by extracorporeal absorption or neutralised by systemic administration of synthetic epitope mimics. Only patients bearing agonistic β1AR autoantibodies in their bloodstream will benefit from these approaches. Therefore, reliable detection of agonistic β1AR autoantibodies is a key pre-requisite for the future implementation of these strategies. β1AR autoantibodies impact on conformation and down-stream signalling of the receptor by binding a conformational epitope, which is poorly represented by synthetic mimics and readily destroyed by fixation. Consequently, β1AR autoantibodies can reliably be detected only by assays utilising the native β1AR as a test antigen. To provide a sufficient basis for diagnostic predictions or therapeutic decisions, one must also determine whether β1AR autoantibodies stimulate the receptor, which again requires native, cell-based reporter systems. Translation of these procedures into versatile diagnostic tests fitting the requirements of general health care is a challenge for future development. Here, we will review the state of diagnostic and therapeutic efforts in the field of β1AR-directed autoimmunity, thereby aiming to furnish a conceptual frame for the further development of novel, more reliable diagnostic tools and more specific antibody-targeted therapeutic concepts

Negative regulation of mitochondrial transcription by mitochondrial topoisomerase I

Mitochondrial topoisomerase I is a genetically distinct mitochondria-dedicated enzyme with a crucial but so far unknown role in the homeostasis of mitochondrial DNA metabolism. Here, we present data suggesting a negative regulatory function in mitochondrial transcription or transcript stability. Deficiency or depletion of mitochondrial topoisomerase I increased mitochondrial transcripts, whereas overexpression lowered mitochondrial transcripts, depleted respiratory complexes I, III and IV, decreased cell respiration and raised superoxide levels. Acute depletion of mitochondrial topoisomerase I triggered neither a nuclear mito-biogenic stress response nor compensatory topoisomerase II beta upregulation, suggesting the concomitant increase in mitochondrial transcripts was due to release of a local inhibitory effect. Mitochondrial topoisomerase I was co-immunoprecipitated with mitochondrial RNA polymerase. It selectively accumulated and rapidly exchanged at a subset of nucleoids distinguished by the presence of newly synthesized RNA and/or mitochondrial RNA polymerase. The inactive Y559F-mutant behaved similarly without affecting mitochondrial transcripts. In conclusion, mitochondrial topoisomerase I dampens mitochondrial transcription and thereby alters respiratory capacity. The mechanism involves selective association of the active enzyme with transcriptionally active nucleoids and a direct interaction with mitochondrial RNA polymerase. The inhibitory role of topoisomerase I in mitochondrial transcription is strikingly different from the stimulatory role of topoisomerase I in nuclear transcription