Phenomenon of reproductive plasticity in ants.

Ant colonies are organized in castes with distinct behaviors that together allow the colony to strive. Reproduction relies on one or a few queens that stay in the nest producing eggs, while females of the worker caste do not reproduce and instead engage in colony maintenance and brood caretaking. Yet, in spite of this clear separation of functions, workers can become reproductive under defined circumstances. Here, we review the context in which workers become reproductive, exhibiting asexual or sexual reproduction depending on the species. Remarkably, the activation of reproduction in these workers can be quite stable, with changes that include behavior and a dramatic extension of lifespan. We compare these changes between species that do or do not have a queen caste. We discuss how the mechanisms underlying reproductive plasticity include changes in hormonal functions and in epigenetic configurations. Further studies are warranted to elucidate not only how reproductive functions have been gradually restricted to the queen caste during evolution but also how reproductive plasticity remains possible in workers of some species.

Caste Transition and Reversion in Harpegnathos saltator Ant Colonies.

Living organisms possess the ability to respond to environmental cues and adapt their behaviors and physiologies for survival. Eusocial insects, such as ants, bees, wasps, and termites, have evolved advanced sociality: living together in colonies where individuals innately develop into reproductive and non-reproductive castes. These castes exhibit remarkably distinct behaviors and physiologies that support their specialized roles in the colony. Among ant species, Harpegnathos saltator females stand out with their highly plastic caste phenotypes that can be easily manipulated in a laboratory environment. In this protocol, we provide detailed instructions on how to generate H. saltator ant colonies, define castes based on behavioral and physiological phenotypes, and experimentally induce caste switches, including the transition from a non-reproductive worker to a reproductive gamergate and vice versa (known as reversion). The unusual features of H. saltator make it a valuable tool to investigate cellular and molecular mechanisms underlying phenotypic plasticity in eusocial organisms. Key features H. saltator is one of few ant species showing remarkable caste plasticity with striking phenotypic changes, being a useful subject for studying behavioral plasticity. Caste switches in H. saltator can be easily manipulated in a controlled laboratory environment by controlling the presence of reproductive females in a colony. The relatively large size of H. saltator females allows researchers to dissect various tissues of interest and conduct detailed phenotypic analyses.

Insulin signaling in the long-lived reproductive caste of ants.

In most organisms, reproduction is correlated with shorter life span. However, the reproductive queen in eusocial insects exhibits a much longer life span than that of workers. In Harpegnathos ants, when the queen dies, workers can undergo an adult caste switch to reproductive pseudo-queens (gamergates), exhibiting a five-times prolonged life span. To explore the relation between reproduction and longevity, we compared gene expression during caste switching. Insulin expression is increased in the gamergate brain that correlates with increased lipid synthesis and production of vitellogenin in the fat body, both transported to the egg. This results from activation of the mitogen-activated protein kinase (MAPK) branch of the insulin signaling pathway. By contrast, the production in the gamergate developing ovary of anti-insulin Imp-L2 leads to decreased signaling of the AKT/forkhead box O (FOXO) branch in the fat body, which is consistent with their extended longevity.

Generation of Functional Genetic Study Models in Zebrafish Using CRISPR-Cas9.

CRISPR-Cas9 is a method for genome editing that can be used efficiently for in vivo applications; the basic implementation of this method is used to generate genome site-directed sequence eliminations. Here we describe a protocol for genome editing using CRISPR-Cas9 in zebrafish (Danio rerio) one-cell embryos.

CTCF knockout reveals an essential role for this protein during the zebrafish development.

Chromatin regulation and organization are essential processes that regulate gene activity. The CCCTC-binding factor (CTCF) is a protein with different and important molecular functions related with chromatin dynamics. It is conserved since invertebrates to vertebrates, posing it as a factor with an important role in the physiology. In this work, we aimed to understand the distribution and functional relevance of CTCF during the embryonic development of the zebrafish (Danio rerio). We generated a zebrafish specific anti-Ctcf antibody, and found this protein to be ubiquitous, through different stages and tissues. We used the CRISPR-Cas9 system to induce molecular alterations in the locus. This resulted in early lethality. We delayed the lethality performing knockdown morpholino experiments, and found an aberrant embryo morphology involving malformations in structures through all the length of the embryo. These phenotypes were rescued with human CTCF mRNA injections, showing the specificity of the morpholinos and a partial functional conservation between the fish and the human proteins. Lastly, we found that the pro-apoptotic genes p53 and bbc3/PUMA are deregulated in the ctcf morpholino-injected embryos. In conclusion, CTCF is a ubiquitous factor during the zebrafish development, which regulates the correct formation of different structures of the embryo, and its deregulation impacts on essential cell survival genes. Overall, this work provides a basis to look for the particular functions of CTCF in the different developing tissues and organs of the zebrafish.

Age-dependent increment of hydroxymethylation in the brain cortex in the triple-transgenic mouse model of Alzheimer's disease.

Alzheimer's disease (AD) is a complex disorder whose etiology is associated with environmental and genetic factors. Recently there have been several attempts to analyze the role of epigenetic alterations in the origin and progression of this neurodegenerative condition. To evaluate the potential participation of the methylation status of the genome that may contribute to AD progression, we have studied the levels and distribution of the 5-methylcytosine and 5-hydroxymethylcytosine in different brain regions at different ages. We analyzed and quantified the immunosignal of these two epigenetic marks in young versus old wild-type mice and in the triple-transgenic mouse model of AD (3xTg-AD). The results show a decline in global 5-methylcytosine mark over time in all studied brain regions concomitant with a significant and widespread increase in 5-hydroxymethylcytosine mark in the aged transgenic mice in contrast to the age-matched controls. These differences in the methylation pattern of brain DNA in the 3xTg-AD that accumulates along age indicates abnormal formation of permissive chromatin structure associated with the increase in AD-related markers.