Patterns of metastatic progression and association with clinical outcomes in canine osteosarcoma: A necropsy study of 83 dogs.

Osteosarcoma is a highly metastatic primary bone tumour that occurs spontaneously in both pet dogs and humans. Patterns of metastasis to organs beyond the most common site (lung) are poorly characterised and it is unknown whether specific associations between patterns of metastatic progression and patient features exist. This retrospective study characterised the necropsy findings of 83 dogs receiving standardised therapy and clinical monitoring in a prospective clinical trial setting to document patterns of metastasis and correlate outcomes with these patterns and other patient and tumour-specific factors. A total of 20 different sites of metastasis were documented, with lung as the most common site, followed by bone, kidney, liver, and heart. Two distinct clusters of dogs were identified based on patterns of metastasis. There was no significant association between site of enrollment, trial arm, sex, serum alkaline phosphatase (ALP) activity, or tumour location and clinical outcomes. A second cancer type was identified at necropsy in 10 dogs (10/83; 12%). These data showcase the extensive nature of osteosarcoma metastasis beyond the lung and provide a benchmark for clinical monitoring of the disease. Further, this study provides insight into transcriptional features of primary tumours that may relate to a propensity for osteosarcoma metastasis to specific organs and tissues.

Apolipoprotein E is a kinetic but not a thermodynamic inhibitor of amyloid formation: implications for the pathogenesis and treatment of Alzheimer disease.

The apolipoprotein E4 (APOE4) allele is associated with an early age of onset of the nonfamilial form of Alzheimer disease (AD) and with increased beta protein amyloid deposition in the brain. These two observations may both arise from an effect of the apoE family of proteins on the rate of in vivo amyloidogenesis. We report here that apoE3, the common apoE isoform, is an in vitro amyloid nucleation inhibitor at physiological concentrations. A significant delay in the onset of amyloid fibril formation by the beta-amyloid protein of AD (beta 1-40) was observed at a low apoE3 concentration (40 nM), corresponding to an apoE3/beta protein molar ratio of 1:1000. The inhibitory activity of a proteolytic fragment of apoE3, containing the N-terminal 191 amino acids, is comparable to the native protein, whereas the C-terminal fragment has no activity. ApoE4 is equipotent or slightly less potent than apoE3, which may be due to its inability to form a disulfide dimer, since the apoE3 dimer is a significantly more potent nucleation inhibitor than apoE4. Neither apoE3 nor apoE4 inhibits the seeded growth of amyloid or affects the solubility or structure of the amyloid fibrils, indicating that apoE is not a thermodynamic amyloid inhibitor. We propose that the linkage between the APOE4 allele and AD reflects the reduced ability of APOE4 homozygotes to suppress in vivo amyloid formation.

The C-terminus of the beta protein is critical in amyloidogenesis.

The beta amyloid protein found in extracellular deposits in Alzheimer's disease (AD) is heterogeneous at its C-terminus; proteins ending at residues 40, 42, and 43 have been identified in neuritic deposits, while protein in vascular amyloid appears to end at residue 39 or 40. Studies of synthetic beta proteins (beta 1-39, beta 1-40, beta 1-42), and model peptides (beta 26-39, beta 26-40, beta 26-42, beta 26-43) demonstrate that amyloid formation is a nucleation-dependent phenomenon. Peptides ending at residues 39 or 40 were kinetically soluble for hours to days, while peptides ending at residues 42 or 43 aggregated immediately; all eventually reached similar thermodynamic solubility. The kinetically soluble variants could be seeded with the kinetically insoluble variants. The secondary structure of beta 26-39 fibrils was different from that of beta 26-42 fibrils, however, seeding beta 26-39 with beta 26-42 produces mixed fibrils with structure similar to beta 26-42. These results suggest that neuritic plaques may be seeded by their minor component; this may determine the structure and properties of amyloid in AD.

The carboxy terminus of the beta amyloid protein is critical for the seeding of amyloid formation: implications for the pathogenesis of Alzheimer's disease.

Several variants of the beta amyloid protein, differing only at their carboxy terminus (beta 1-39, beta 1-40, beta 1-42, and beta 1-43), have been identified as the major components of the cerebral amyloid deposits which are characteristic of Alzheimer's disease. Kinetic studies of aggregation by three naturally occurring beta protein variants (beta 1-39, beta 1-40, beta 1-42) and four model peptides (beta 26-39, beta 26-40, beta 26-42, beta 26-43) demonstrate that amyloid formation, like crystallization, is a nucleation-dependent phenomenon. This discovery has practical consequences for studies of the beta amyloid protein. The length of the C-terminus is a critical determinant of the rate of amyloid formation ("kinetic solubility") but has only a minor effect on the thermodynamic solubility. Amyloid formation by the kinetically soluble peptides (e.g., beta 1-39, beta 1-40, beta 26-39, beta 26-40) can be nucleated, or "seeded", by peptides which include the critical C-terminal residues (beta 1-42, beta 26-42, beta 26-43, beta 34-42). These results suggest that nucleation may be the rate-determining step of in vivo amyloidogenesis and that beta 1-42 and/or beta 1-43, rather than beta 1-40, may be the pathogenic protein(s) in AD.