Considerations for non-clinical safety studies of therapeutic peptide vaccines.

Guidelines for non-clinical studies of prophylactic vaccines against infectious diseases have been published widely, but similar guidelines for therapeutic vaccines, and especially therapeutic peptide vaccines, have yet to be established. The approach to non-clinical safety studies required for therapeutic vaccines differs from that for prophylactic vaccines due to differences in the risk-benefit balance and the mechanisms of action. We propose the following guidelines for non-clinical safety studies for therapeutic peptide vaccines. (i) Since the main safety concern is related to the immune response that might occur at normal sites that express a target antigen, identification of these possible target sites using in silico human expression data is important. (ii) Due to the strong dependence on HLA, it is not feasible to replicate immune responses in animals. Thus, the required non-clinical safety studies are characterized as those detecting off-target toxicity rather than on-target toxicity.

Conservation of novel Mahya genes shows the existence of neural functions common between Hymenoptera and Deuterostome.

Honeybees have been shown to exhibit cognitive performances that were thought to be specific to some vertebrates. However, the molecular and cellular mechanisms of such cognitive abilities of the bees have not been understood. We have identified a novel gene, Mahya, expressed in the brain of the honeybee, Apis mellifera, and other Hymenoptera. Mahya orthologues are present in Deuterostomes but are absent or highly diverged in nematodes and, intriguingly, in two dipteran insects (fruit fly and mosquito) and Lepidoptera (silk moth). Mahya genes encode novel secretory proteins with a follistatin-like domain (Kazal-type serine/threonine protease inhibitor domain and EF-hand calcium-binding domain), two immunoglobulin domains, and a C-terminal novel domain. Honeybee Mahya is expressed in the mushroom bodies and antennal lobes of the brain. Zebra fish Mahya orthologues are expressed in the olfactory bulb, telencephalon, habenula, optic tectum, and cerebellum of the brain. Mouse Mahya orthologues are expressed in the olfactory bulb, hippocampus, and cerebellum of the brain. These results suggest that Mahya may be involved in learning and memory and in processing of sensory information in Hymenoptera and vertebrates. Furthermore, the limited existence of Mahya in the genomes of Hymenoptera and Deuterostomes supports the hypothesis that the genes typically represented by Mahya were lost or highly diverged during the evolution of the central nervous system of specific Bilaterian branches under the specific selection and subsequent adaptation associated with different ecologies and life histories.

The changes of gene expression in honeybee (Apis mellifera) brains associated with ages.

Honeybee (Apis mellifera) worker bees (workers) are known to perform wide variety of tasks depending on their ages. The worker's brains also show the activity and behavior-dependent chemical and structural plasticity. To test if there are any changes of gene expression associated with different ages in the worker brains, we compared the gene expression patterns between the brains of newly emerged bees and old foraging workers (foragers) by macroarray analysis. The expression of genes encoding signal transduction pathway components, ion channels, and neurotransmitter transporters is elevated in the old forager brains, suggesting that the neuronal activities would be enhanced. The mRNA levels of cell adhesion protein, transcription related factors, and plasma membrane associated proteins are also increased in the old forager brains. Meanwhile, the mRNA level of one putative cell adhesion protein is decreased in the old forager brains. These results thus suggest that the dramatic changes of gene expression occur in honeybee brains associated with ages.