Metamemory entails cognitively assessing the strength of one’s memories. We tested the ability of nine Long-Evans rats to distinguish between remembering and forgetting by presenting a decline option that allowed a four-choice odor-based delayed match to sample (DMTS) tests to be by-passed. Rats performed significantly better on tests they chose to take than on tests they were forced to take, indicating metacognitive responding. However, rather than control by internal mnemonic cues, one alternative explanation is that decline use is based on external test-specific cues that become associated with increased rewards overtime. To examine this possibility, we tested rats on three generalization tests in which external contingencies were inconsistent and therefore could not serve as discriminative cues. Rats transferred adaptive use of the decline response in tests that eliminated memory by presenting no sample, increased memory by presenting multiple samples, and both weakened and strengthened memory by varying the retention interval. Further, subjects chose to take or decline the test before encountering the memory test, providing evidence that rats based their metacognitive responding on internal cues rather than external ones. To our knowledge, this is the first robust evidence for metamemory in rats using the DMTS decline-test paradigm in which several possible sources of external stimulus control can be ruled out.
Metamemory involves the cognitive ability to assess the strength of one's memories. To explore the possibility of metamemory in non-human animals, numerous behavioral tasks have been created, many of which utilize an option to decline memory tests. To assess metamemory in rats, we utilized this decline-test option paradigm by adapting previous visual delayed-match-to-sample tests (DMTS)12 developed for primate species to an odor-based test suitable for rodents. First, rats are given a sample to remember by digging in a cup of scented sand. After a delay, the rat is presented with four distinctly scented cups, one of which contains the identical scent experienced during the sample; if this matching cup is selected, then the rat obtains a preferred, larger reward. Selection of any of the other three non-matching sand-filled scented cups results in no reward. Retention intervals are individually titrated such that subjects perform between 40 and 70% correct, therefore ensuring rats sometimes remember and sometimes forget the sample. Here, the operational definition of metamemory is the ability to distinguish between the presence and absence of memory through behavioral responding. Towards this end, on two-thirds of trials, a decline option is presented in addition to the four choice cups (choice trials). If the decline-test option- an unscented colored sand cup, is selected, the subject receives a smaller less-preferred reward and avoids the memory test. On the remaining third of trials, the decline-test option is not available (forced trials), causing subjects to guess the correct cup when the sample is forgotten. On choice tests, subjects that know when they remember should select the decline option when memory is weak rather than take the test and choose incorrectly. Therefore, significantly higher performance on chosen tests as compared to forced memory tests is indicative of the adaptive use of the decline-test response and metacognitive responding.
Approximately 20 TP53 retrogenes exist in the African and Asian elephant genomes (Loxodonta Africana, Elephas Maximus) in addition to a conserved TP53 gene that encodes a full-length protein. Elephant TP53-RETROGENE 9 (TP53-R9) encodes a p53 protein (p53-R9) that is truncated in the middle of the canonical DNA binding domain. This C-terminally truncated p53 retrogene protein lacks the nuclear localization signals and oligomerization domain of its full-length counterpart. When expressed in human osteosarcoma cells (U2OS), p53-R9 binds to Tid1, the chaperone protein responsible for mitochondrial translocation of human p53 in response to cellular stress. Tid1 expression is required for p53-R9-induced apoptosis. At the mitochondria, p53-R9 binds to the pro-apoptotic BCL-2 family member Bax, which leads to caspase activation, cytochrome c release, and cell death. Our data show, for the first time, that expression of this truncated elephant p53 retrogene protein induces apoptosis in human cancer cells. Understanding the molecular mechanism by which the additional elephant TP53 retrogenes function may provide evolutionary insight that can be utilized for the development of therapeutics to treat human cancers.
Elephants naturally have low rates of cancer, potentially due to evolved genetic changes in tumor suppressor elephant TP53 (EP53) and amplification of 19 TP53 retrogenes. A better understanding of the mechanisms of cancer suppression in elephants by EP53 and its retrogenes could lead to more effective human cancer therapeutics. EP53 induces a strong apoptotic response compared to human TP53, especially when combined with EP53-RETROGENE 9 (EP53-R9). EP53-R9 encodes a truncated p53 protein that induces apoptosis of human cancer cells independent of EP53 through a transcription-independent mechanism. To characterize EP53 and EP53-R9’s role in cancer suppression, transgenic mice were generated to replace mouse TRP53 with EP53. Additionally, a tetracycline inducible EP53-R9 gene was inserted into a safe harbor locus in mice. Carcinogenesis studies with 3-Methylcholanthene injection revealed that EP53 mice survived significantly longer compared to heterozygous or homozygousTRP53 mice (p <0.0001, 0.0102). Experiments to assess the protective role of EP53-R9 alone and combined with EP53 are ongoing. Several mouse embryonic fibroblast (MEF) cell lines were generated from these transgenic mice with 14 distinct genotypes with different combinations of TRP53, EP53, and EP53-R9. p53 target gene expression studies showed that MEFs with EP53 induce higher expression of MDM2 and p21 compared to TRP53-containing MEFs, suggesting that the cancer-protective effect observed in EP53 mice is due, in part, to greater activation of p53 signaling. These results support the need for future work to assess the potential of EP53-based therapeutics for human cancer. Citation Format: Lisa M. Abegglen, Jared S. Fowles, Aidan J. Preston, Aaron Rogers, Niraja Bhachech, Brayden B. Barney, Ryan Kennington, David H. Lum, Gareth Mitchell, Joshua D. Schiffman. Elephant p53 protects mice from carcinogen induced death [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 45.
Is visual perception “rich” or “sparse?” One finding supporting the “rich” hypothesis shows that a specific visual summary representation, color variability, is represented “cost-free” outside focally-attended regions in dual-task paradigms (Bronfman et al. 2014). Here, we investigated whether this “cost-free” phenomenon for color variability perception extends to peripheral vision. We performed three experiments: in our first experiment, we replicated previous findings and verified that color variability is represented “cost-free” in central vision. In our second experiment, we extended the paradigm to peripheral vision and found that in minimally-attended regions of space, color variability perception was impaired. In a third and final experiment, we added confidence judgments to our task, and found that participants maintained high levels of metacognitive awareness of impaired performance in minimally-attended regions of space. These findings provide evidence which challenges common conceptions on both sides of the rich vs. sparse debate.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.