Effects of go/no-go training on food-related action tendencies, liking and choice.

Inhibitory control training effects on behaviour (e.g. 'healthier' food choices) can be driven by changes in affective evaluations of trained stimuli, and theoretical models indicate that changes in action tendencies may be a complementary mechanism. In this preregistered study, we investigated the effects of food-specific go/no-go training on action tendencies, liking and impulsive choices in healthy participants. In the training task, energy-dense foods were assigned to one of three conditions: 100% inhibition (no-go), 0% inhibition (go) or 50% inhibition (control). Automatic action tendencies and liking were measured pre- and post-training for each condition. We found that training did not lead to changes in approach bias towards trained foods (go and no-go relative to control), but we warrant caution in interpreting this finding as there are important limitations to consider for the employed approach-avoidance task. There was only anecdotal evidence for an effect on food liking, but there was evidence for contingency learning during training, and participants were on average less likely to choose a no-go food compared to a control food after training. We discuss these findings from both a methodological and theoretical standpoint and propose that the mechanisms of action behind training effects be investigated further.

Fission yeast Cdc23/Mcm10 functions after pre-replicative complex formation to promote Cdc45 chromatin binding.

Using a cytological assay to monitor the successive chromatin association of replication proteins leading to replication initiation, we have investigated the function of fission yeast Cdc23/Mcm10 in DNA replication. Inactivation of Cdc23 before replication initiation using tight degron mutations has no effect on Mcm2 chromatin association, and thus pre-replicative complex (pre-RC) formation, although Cdc45 chromatin binding is blocked. Inactivating Cdc23 during an S phase block after Cdc45 has bound causes a small reduction in Cdc45 chromatin binding, and replication does not terminate in the absence of Mcm10 function. These observations show that Cdc23/Mcm10 function is conserved between fission yeast and Xenopus, where in vitro analysis has indicated a similar requirement for Cdc45 binding, but apparently not compared with Saccharomyces cerevisiae, where Mcm10 is needed for Mcm2 chromatin binding. However, unlike the situation in Xenopus, where Mcm10 chromatin binding is dependent on Mcm2-7, we show that the fission yeast protein is bound to chromatin throughout the cell cycle in growing cells, and only displaced from chromatin during quiescence. On return to growth, Cdc23 chromatin binding is rapidly reestablished independently from pre-RC formation, suggesting that chromatin association of Cdc23 provides a link between proliferation and competence to execute DNA replication.

Sequencing and comparative analysis of the gorilla MHC genomic sequence.

Major histocompatibility complex (MHC) genes play a critical role in vertebrate immune response and because the MHC is linked to a significant number of auto-immune and other diseases it is of great medical interest. Here we describe the clone-based sequencing and subsequent annotation of the MHC region of the gorilla genome. Because the MHC is subject to extensive variation, both structural and sequence-wise, it is not readily amenable to study in whole genome shotgun sequence such as the recently published gorilla genome. The variation of the MHC also makes it of evolutionary interest and therefore we analyse the sequence in the context of human and chimpanzee. In our comparisons with human and re-annotated chimpanzee MHC sequence we find that gorilla has a trimodular RCCX cluster, versus the reference human bimodular cluster, and additional copies of Class I (pseudo)genes between Gogo-K and Gogo-A (the orthologues of HLA-K and -A). We also find that Gogo-H (and Patr-H) is coding versus the HLA-H pseudogene and, conversely, there is a Gogo-DQB2 pseudogene versus the HLA-DQB2 coding gene. Our analysis, which is freely available through the VEGA genome browser, provides the research community with a comprehensive dataset for comparative and evolutionary research of the MHC.

Lessons learned from the initial sequencing of the pig genome: comparative analysis of an 8 Mb region of pig chromosome 17.

BACKGROUND: We describe here the sequencing, annotation and comparative analysis of an 8 Mb region of pig chromosome 17, which provides a useful test region to assess coverage and quality for the pig genome sequencing project. We report our findings comparing the annotation of draft sequence assembled at different depths of coverage. RESULTS: Within this region we annotated 71 loci, of which 53 are orthologous to human known coding genes. When compared to the syntenic regions in human (20q13.13-q13.33) and mouse (chromosome 2, 167.5 Mb-178.3 Mb), this region was found to be highly conserved with respect to gene order. The most notable difference between the three species is the presence of a large expansion of zinc finger coding genes and pseudogenes on mouse chromosome 2 between Edn3 and Phactr3 that is absent from pig and human. All of our annotation has been made publicly available in the Vertebrate Genome Annotation browser, VEGA. We assessed the impact of coverage on sequence assembly across this region and found, as expected, that increased sequence depth resulted in fewer, longer contigs. One-third of our annotated loci could not be fully re-aligned back to the low coverage version of the sequence, principally because the transcripts are fragmented over several contigs. CONCLUSION: We have demonstrated the considerable advantages of sequencing at increased read depths and discuss the implications that lower coverage sequence may have on subsequent comparative and functional studies, particularly those involving complex loci such as GNAS.

Genomic sequence of the class II region of the canine MHC: comparison with the MHC of other mammalian species.

The domestic dog, Canis familiaris, is an excellent model species in which to study complex inherited diseases, having over 200 recognized breeds, each of which represents a closed gene pool. Overlapping canine genomic BAC clones were sequenced to obtain 711,521 bp of the canine classical and extended MHC class II regions. Analysis and annotation of this sequence reveals that it contains 45 loci, of which 29 are predicted to be functionally expressed. Comparison of the DLA class II sequence with those of the cat, human, and mouse highlights regions of syntenic conservation and species-specific gene rearrangement and duplication and gives an insight into the evolution of the DR region in the order Carnivora. Elucidation of functionally important dog class II genes and the identification of 23 microsatellite markers spanning this region will contribute significantly to the study of canine diseases that have an immune component.

Fission yeast Cdc23 interactions with DNA replication initiation proteins.

Schizosaccharomyces pombe Cdc23 is an essential DNA replication protein, conserved in eukaryotes and functionally homologous with Saccharomyces cerevisiae Dna43 (Mcm10). We sought evidence for interactions between Cdc23 and the MCM2-7 complex, a component of both the pre-replicative complex and the replication fork. Cdc23 shows genetic interactions with four MCM subunits: cdc23-M36 and cdc23-1E2 alleles both show synthetic phenotypes with mcm2 (cdc19-P1) and mcm6 (mis5-268), and cdc23-M36 is synthetically lethal with mcm4 (cdc21-K46) and with mcm5 (nda4-108). The wild-type cdc23 gene on multicopy plasmids can partially suppress temperature-dependent defects in mcm5 (nda4-108). Two-hybrid analysis demonstrates interactions at the protein-protein level between Cdc23 and Mcm4, Mcm5 and Mcm6. Cdc23 also interacts with four subunits of the Schizosaccharomyces pombe origin recognition complex (ORC) in yeast two-hybrid assay: Orc1, Orc2, Orc5 and Orc6. We found no evidence for interaction between Cdc23 and the MCM recruitment factor Cdc18 (the homologue of Saccharomyces cerevisiae Cdc6). Unlike Cdc18, Cdc23 mRNA shows no significant fluctuation in level through the cell cycle. These data suggest that fission yeast Cdc23 is an MCM-associated factor which has a role in the initiation of DNA replication.