Novel Aspects of cAMP-Response Element Modulator (CREM) Role in Spermatogenesis and Male Fertility.

Spermatogenesis is a very complex process with an intricate transcriptional regulation. The transition from the diploid to the haploid state requires the involvement of specialized genes in meiosis, among other specific functions for the formation of the spermatozoon. The transcription factor cAMP-response element modulator (CREM) is a key modulator that triggers the differentiation of the germ cell into the spermatozoon through the modification of gene expression. CREM has multiple repressor and activator isoforms whose expression is tissue-cell-type specific and tightly regulated by various factors at the transcriptional, post-transcriptional and post-translational level. The activator isoform CREMτ controls the expression of several relevant genes in post-meiotic stages of spermatogenesis. In addition, exposure to xenobiotics negatively affects CREMτ expression, which is linked to male infertility. On the other hand, antioxidants could have a positive effect on CREMτ expression and improve sperm parameters in idiopathically infertile men. Therefore, CREM expression could be used as a biomarker to detect and even counteract male infertility. This review examines the importance of CREM as a transcription factor for sperm production and its relevance in male fertility, infertility and the response to environmental xenobiotics that may affect CREMτ expression and the downstream regulation that alters male fertility. Also, some health disorders in which CREM expression is altered are discussed.

Giardia duodenalis enolase is secreted as monomer during trophozoite-epithelial cell interactions, activates plasminogen and induces necroptotic damage.

Enolase, a multifunctional protein expressed by multiple pathogens activates plasminogen to promote proteolysis on components of the extracellular matrix, an important event in early host-pathogen interactions. A secreted form of enolase that is released upon the interaction of trophozoites with epithelial cells has been detected in the secretome of G. duodenalis. However, the role of enolase in the host-pathogen interactions remains largely unknown. In this work, the effects of G. duodenalis enolase (Gd-eno) on the epithelial cell model (IEC-6) were analyzed. Firstly, the coding sequence of Giardia enolase was cloned and the recombinant protein used to raise antibodies that were then used to define the localization and role of enolase in epithelial cell-trophozoite interactions. Gd-eno was detected in small cytoplasmic vesicles as well as at the surface and is enriched in the region of the ventral disk of Giardia trophozoites. Moreover, the blocking of the soluble monomeric form of the enzyme, which is secreted upon interaction with IEC-6 cells by the anti-rGd-eno antibodies, significantly inhibited trophozoite attachment to intestinal IEC-6 cell monolayers. Further, rGd-eno was able to bind human plasminogen (HsPlg) and enhanced plasmin activity in vitro when the trophozoites were incubated with the intrinsic plasminogen activators of epithelial cells. In IEC-6 cells, rGd-eno treatment induced a profuse cell damage characterized by copious vacuolization, intercellular separation and detachment from the substrate; this effect was inhibited by either anti-Gd-eno Abs or the plasmin inhibitor ϵ- aminocaproic acid. Lastly, we established that in epithelial cells rGd-eno treatment induced a necroptotic-like process mediated by tumor necrosis factor α (TNF-α) and the apoptosis inducing factor (AIF), but independent of caspase-3. All together, these results suggest that Giardia enolase is a secreted moonlighting protein that stimulates a necroptotic-like process in IEC-6 epithelial cells via plasminogen activation along to TNFα and AIF activities and must be considered as a virulence factor.

Implementation of a tunable t-CRISPRi system for gene regulation in Giardia duodenalis.

Giardia duodenalis, is a binuclear and microaerophilic protozoan that causes giardiasis. Up to date, several molecular approaches have been taken to understand the molecular mechanisms of diverse cellular processes in this parasitic protozoan. However, the role of many genes involved in these processes needs further analysis. The CRISPR interference (CRISPRi) system has been widely used, as a constitutive expression system for gene silencing purposes in several parasites, including Giardia. The aim of this work was to implement a tunable t-CRISPRi system in Giardia to silence abundant, moderately and low expressed genes, by constructing an optimized and inducible plasmid for the expression of both gRNA and dCas9. A doxycycline inducible pRan promoter was used to express dCas9 and each gRNA, consistently dCas9 expression and nuclear localization were confirmed by Western-blot and immunofluorescence in transfected trophozoites. The transcriptional repression was performed on α-tubulin (high expression), giardipain-1 (moderate expression) and Sir2 and Sir4 (low expression) genes. The α-tubulin gene knock-down caused by dCas9 doxycycline-induction was confirmed by a decrease in its protein expression which was of 50% and 60% at 24 and 48 h, respectively. This induced morphological alterations in flagella. The giardipain-1 knock down, showed a decrease in protein expression of 40 and 50% at 12 and 24 h, respectively, without affecting trophozoites viability, consistent with this a zymogram analysis on giardipain-1 knock down revealed a decrease in giardipain-1 protease activity. When repressing sirtuins expression, a total repression was obtained but trophozoites viability was compromised. This approach provides a molecular tool for a tailored repression to produce specific gene knockdowns.

Giardia duodenalis carries out canonical homologous recombination and single-strand annealing.

In the past decades, the ability of Giardia duodenalis to perform homologous recombination has been suggested, supported by the observations of genomic integration of foreign plasmids and the disruption of genes using CRISPR technology. Unfortunately, the direct study of a HR mechanism has not been addressed, which would be pertinent in a minimalist organism lacking fundamental DNA-repair elements and even complete pathways. In addition, the constant ploidy changes through the life cycle of this parasite highlight the conservation and relevance of homologous recombination in maintaining genomic stability. In this research, we analyzed different recombinable plasmid systems and their outcomes after G. duodenalis transfection, using this approach we determined genomic, intra-plasmid and inter-plasmid recombination, moreover, we examined the presence of the non-conservative single-strand annealing pathway. With the intention of corroborating that the observed processes were done by homologous recombination, we used a chemical inhibitor named Mirin, which specifically inhibits Mre11 3'- 5' exonuclease activity, one of the first steps involved in homologous recombination and fundamental to success in repairing. Overall, these results describe the multiple recombinational substrates used by G. duodenalis to achieve HR and demonstrate the presence and use of single-strand annealing recombination.

Cancer in Amphibia, a rare phenomenon?

Compared to other animals, the spontaneous occurrence of tumors in wild amphibians is relatively rare, generally limited to specific populations or species. The number of reports of spontaneous tumors in amphibians known up to 1986 was 491 cases in anurans and about 253 cases in urodeles. Similarly, there have been many, unsuccessful attempts to chemically or biologically induce tumors in amphibians. With these considerations, it is inevitable to wonder: do urodeles and anurans have an inherent resistance to cancer? Here, we review the spontaneous and induced occurrence of tumors in amphibians in a timeline, as well as failed attempts to induce tumors in these amphibians. Indeed, recent studies seem to indicate that there is a relationship between regeneration and cancer because regenerating tissues seem to resist tumorigenesis, as opposed to nonregenerative tissues of the same amphibian models. Although the mechanisms that allow regenerating tissues to resist tumorigenesis have not been elucidated, it is worth to note that, in addition to the apparent relationship between regeneration and cancer, amphibians possess characteristics that could contribute to their ability to resist the development of neoplastic events. The implications of these features in cancer susceptibility are discussed.

Evidence of requirement for homologous-mediated DNA repair during Ambystoma mexicanum limb regeneration.

BACKGROUND: Limb regeneration in the axolotl is achieved by epimorphosis, thus depending on the blastema formation, a mass of progenitor cells capable of proliferating and differentiating to recover all lost structures functionally. During regeneration, the blastema cells accelerate the cell cycle and duplicate its genome, which is inherently difficult to replicate because of its length and composition, thus being prone to suffer double-strand breaks. RESULTS: We identified and characterized two remarkable components of the homologous recombination repair pathway (Amex.RAD51 and Amex.MRE11), which were heterologously expressed, biochemically characterized, and inhibited by specific chemicals. These same inhibitors were applied at different time points after amputation to study their effects during limb regeneration. We observed an increase in cellular senescent accompanied by a slight delay in regeneration at 28 days postamputation regenerated tissues; moreover, inhibitors caused a rise in the double-strand break signaling as a response to the inhibition of the repair mechanisms. CONCLUSIONS: We confirmed the participation and importance of homologous recombination during limb regeneration. The chemical inhibition induces double-strand breaks that lead to DNA damage associated senescence, or in an alternatively way, this damage could be possibly repaired by a different DNA repair pathway, permitting proper regeneration and avoiding senescence.

MPS1 is involved in the HPV16-E7-mediated centrosomes amplification.

BACKGROUND: It has been reported that the oncoprotein E7 from human papillomavirus type 16 (HPV16-E7) can induce the excessive synthesis of centrosomes through the increase in the expression of PLK4, which is a transcriptional target of E2F1. On the other hand, it has been reported that increasing MPS1 protein stability can also generate an excessive synthesis of centrosomes. In this work, we analyzed the possible role of MPS1 in the amplification of centrosomes mediated by HPV16-E7. RESULTS: Employing qRT-PCR, Western Blot, and Immunofluorescence techniques, we found that E7 induces an increase in the MPS1 transcript and protein levels in the U2OS cell line, as well as protein stabilization. Besides, we observed that inhibiting the expression of MPS1 in E7 protein-expressing cells leads to a significant reduction in the number of centrosomes. CONCLUSIONS: These results indicate that the presence of the MPS1 protein is necessary for E7 protein to increase the number of centrosomes, and possible implications are discussed.

An update on cell division of Giardia duodenalis trophozoites.

Giardia duodenalis is a flagellated protozoan that is responsible for many cases of diarrheal disease worldwide and is characterized by its great divergence from the model organisms commonly used in studies of basic cellular processes. The life cycle of Giardia involves an infectious cyst form and a proliferative and mobile trophozoite form. Each Giardia trophozoite has two nuclei and a complex microtubule cytoskeleton that consists of eight flagellar axonemes, basal bodies, the adhesive disc, the funis and the median body. Since the success of Giardia infecting other organisms depends on its ability to divide and proliferate efficiently, Giardia must coordinate its cell division to ensure the duplication and partitioning of both nuclei and the multiple cytoskeletal structures. The purpose of this review is to summarize current knowledge about cell division and its regulation in this protist.

Giardiavirus: an update.

Giardiavirus is the only virus that infects Giardia duodenalis, a highly prevalent parasite worldwide, especially in low-income and developing countries. This virus belongs to the Totiviridae family, being a relative of other viruses that infect fungi and protozoa. It has a simple structure with only two proteins encoded in its genome and it appears that it can leave the cell without lysis. All these characteristics make it an interesting study model; however, its research has unfortunately made little progress in recent years. Thus, in this review, we summarize the currently available data on Giardiavirus, from their structure, genome and main proteins, to the uses that have been given to them and the possible health applications for the future.

Sirtuin GdSir2.4 participates in the regulation of rRNA transcription in the Giardia duodenalis parasite.

Giardia duodenalis is a parasite of great medical interest due to the number of infections it causes worldwide each year. Although research on epigenetic mechanisms in this protist has only begun recently, epigenetic regulation has already been shown to have important roles in encystation, antigenic variation, and resistance to antibiotics in Giardia. In this work, we show that a Giardia ortholog of Sir2, GdSir2.4, is involved in the silencing of rRNA expression. Our results demonstrate that GdSir2.4 localizes to the nucleolus, and its binding to the intergenic spacer region of the rDNA is associated with the deacetylation of the chromatin in this region. Given the importance of the regulation of rRNA expression to maintain adequate levels of ribosomes and genomic stability within the cells, GdSir2.4 can be considered a target to create new therapeutic agents against this parasite.

Ribosomal DNA in the protozoan parasite Giardia duodenalis has a differential chromatin distribution and epigenetic markings across the subunits.

Giardia duodenalis is a parasite that causes a large number of diarrheal diseases around the world. It is noteworthy that in a large number of processes, Giardia requires fewer components than other eukaryotes, even without some organelles such as mitochondria and peroxisomes. Despite this, core histones are known to exist in Giardia and epigenetic marks have been found on them, suggesting that they somehow control the expression of certain genes. The regulation of the expression of ribosomal DNA (rDNA) is essential, since it is required to maintain adequate levels of ribosomes and, given the nature of tandem repeat, it is a feasible area to create genomic instability. In Giardia, it is not known how this process occurs, but as in other eukaryotes, it is suggested through various epigenetic mechanisms. Thus, in the present work we seek to identify how chromatin is distributed through the Giardia rDNA and if there were histone marks that could control its expression.

DNA repair during regeneration in Ambystoma mexicanum.

The remarkable regenerative capabilities of the salamander Ambystoma mexicanum have turned it into one of the principal models to study limb regeneration. During this process, a mass of low differentiated and highly proliferative cells, called blastema, propagates to reestablish the lost tissue in an accelerated way. Such a process implies the replication of a huge genome, 10 times larger than humans, with about 65.6% of repetitive sequences. These features make the axolotl genome inherently difficult to replicate and prone to bear mutations. In this context, the role of DNA repair mechanisms acquires great relevance to maintain genomic stability, especially if we consider the necessity of ensuring the correct replication and integrity of such a large genome in the blastema cells, which are key for tissue regeneration. On the contrary, DNA damage accumulation in these cells may result in senescence, apoptosis and premature differentiation, all of them are mechanisms employed to avoid DNA damage perpetuation but with the potential to affect the limb regeneration process. Here we review and discuss the current knowledge on the implications of DNA damage responses during salamander regeneration.

Natural Compounds That Target DNA Repair Pathways and Their Therapeutic Potential to Counteract Cancer Cells.

Resistance to current cancer treatments is an important problem that arises through various mechanisms, but one that stands out involves an overexpression of several factors associated with DNA repair. To counteract this type of resistance, different drugs have been developed to affect one or more DNA repair pathways, therefore, to test different compounds of natural origin that have been shown to induce cell death in cancer cells is paramount. Since natural compounds target components of the DNA repair pathways, they have been shown to promote cancer cells to be resensitized to current treatments. For this and other reasons, natural compounds have aroused great curiosity and several research projects are being developed around the world to establish combined treatments between them and radio or chemotherapy. In this work, we summarize the effects of different natural compounds on the DNA repair mechanisms of cancer cells and emphasize their possible application to re-sensitize these cells.

Nicotinamide induces G2 cell cycle arrest in Giardia duodenalis trophozoites and promotes changes in sirtuins transcriptional expression.

Giardia duodenalis is a flagellated unicellular eukaryotic microorganism that commonly causes diarrheal disease throughout the world. Treatment of giardiasis is limited to nitroheterocyclic compounds as metronidazole and benzimidazoles as albendazole, where remarkably treatment failure is relatively common. Consequently, the need for new options to treat this disease is underscored. We predicted by a bioinformatic approach that nicotinamide inhibits Giardia sirtuins by the nicotinamide exchange pathway, and since sirtuins are involved in cell cycle control, they could be related with arrest and decrease of viability. When trophozoites were treated with nicotinamide (NAM), a strong arrest of Giardia trophozoites in G2 phase was observed and at the same time changes in transcriptional expression of sirtuins were produced. Interestingly, the G2 arrest is not related to double-strand breaks, which strengthens the role of sirtuins in the control of the Giardia cell cycle. Results with NAM-treated trophozoites as predicted demonstrate antigiardial effects and thus open new options for the treatment of giardiasis, either with the combination of nicotinamide with another antigiardial drug, or with the design of specific inhibitors for Giardia sirtuins.

Epigenetics in the early divergent eukaryotic Giardia duodenalis: An update.

Giardia duodenalis is a flagellated unicellular eukaryotic microorganism that usually parasitizes the small intestine of humans and many other vertebrates causing diarrheal disease throughout the world. Notably, Giardia despite minimization of most cellular systems shows different strategies to adapt to environmental conditions, evade the immune system and resist exposure to antimicrobial agents. Over the past years, epigenetic regulation of gene expression has been shown to have a relevant role in the parasite's biology. Interestingly, analysis of the Giardia genome revealed the presence of enzymes responsible for post-translational modification in histones, therefore suggesting that epigenetic mechanisms may regulate gene expression in this parasite. Thus, the purpose of this review is to summarize how epigenetic mechanisms play relevant roles in the pathogenicity of Giardia, with a particular emphasis on the molecular mechanisms associated with parasite differentiation, antigenic variation and antimicrobial resistance.

Giardipain-1, a protease secreted by Giardia duodenalis trophozoites, causes junctional, barrier and apoptotic damage in epithelial cell monolayers.

The adhesion of Giardia duodenalis trophozoites to intestinal epithelial cells allows the onset and maintenance of giardiasis. During these interactions, epithelial cells can be committed to apoptosis by enzymes secreted by the parasites, including cysteine proteases that are increasingly identified as virulence factors in parasitic protozoa. In this work, a monoclonal antibody (mAb1G3) raised against G. duodenalis surface components was found to react with a 25 kDa protein expressed in the cell surface and flagella of G. duodenalis trophozoites. When trophozoites expressing this protein were cultured with IEC-6 intestinal epithelial cell monolayers, a dynamic release of this protein was observed with mAbIG3. Proteomic analysis identified the protein as a mature cathepsin B-like (gCatB) enzyme, whose proteolytic activity, detected in zymograms, was eliminated by CatB inhibitor E-64. This protein was named giardipain-1 due to its functional papain-like features and was purified by affinity chromatography using mAbIG3. Upon exposure to the purified, mature and secreted forms of giardipain-1, IEC-6 epithelial cell monolayers displayed membrane blebbing and phosphatidylserine exposure on the outer cell surface, indicating an apoptotic process. In Madin Darby Canine Kidney (MDCK) cell monolayers, giardipain-1 leads to the appearance of pore-like regions and of gaps along cell-cell junctions, to decreased transepithelial electrical resistance (TER), caspase-3 activation and poly-ADP-ribose polymerase (PARP) fragmentation. At early times during exposure, giardipain-1 co-localized at cell-cell junctions, associated with occludin and induced the delocalization and degradation of tight junction proteins occludin and claudin-1. The damage caused to epithelial monolayers by giardipain-1 was blocked by pre-incubation with the CatB B Inhibitor E-64. Furthermore, silencing the giardipain-1 gene in trophozoites lowered the proteolytic activity of giardipain-1 and reduced the damage in IEC-6 monolayers. The damage observed appears to be specific to giardipain activity since almost no damage was observed when IEC-6 monolayers were incubated with papain, a non-related cysteine protease. Hence this study suggests that giardipain-1 triggers, in epithelial cells, degradation of cell-cell junctional components and apoptotic damage, supporting the notion of giardiapain-1 as a virulence factor of Giardia.

Giardia duodenalis Rad52 protein: biochemical characterization and response upon DNA damage.

Giardia duodenalis is a flagellated binucleated protozoan that colonizes the small intestine in mammals, causing giardiasis, acute or chronic diarrhea. DNA double strand break either endogenously or exogenously generated is a major insult to DNA and its repair by homologous recombination (HR) is crucial for genomic stability. During HR, Rad52 plays key roles in the loading of the Rad51 recombinase, and the annealing of the second double-strand break end to the displaced strand of the D-loop structure. Among the functions found in vitro in yeast and human Rad52 protein are: ssDNA or dsDNA binding activity, ability to anneal bare or RPA coated-ssDNA, as well as multimeric ring formation. In this work, we searched for conserved domains in a putative Rad52 protein from G. duodenalis (GdRad52). Its coding sequence was cloned, expressed and purified to study its biochemical properties. rGdRad52 binds to dsDNA and ssDNA, with greater affinity for the latter. Likewise, rGdRad52 promotes annealing of DNA uncoated and coated with GdRPA1. rGdRad52 interacts with GdDMC1B and with GdRPA1 protein as shown in far western blotting assay. Additionally, rGdRad52 formed multimeric rings as observed by electronic microscopy. Finally, GdRad52 is over expressed in response upon DNA damage inflicted on trophozoites.

Ubiquitin-like Atg8 protein is expressed during autophagy and the encystation process in Naegleria gruberi.

Members of the Naegleria genus are free-living amoebae, and the only pathogenic specie described to date for humans is N. fowleri. However, as the complete genome of this specie has not been reported, non-pathogenic N. gruberi is employed to describe molecular pathways in N. fowleri. Regardless, certain mechanisms, such as autophagy, have not yet been characterized in N. gruberi. Autophagy is involved in different cellular processes in some protozoa, including the recycling of unnecessary organelles, development, and cell differentiation. In this work, we characterized autophagy in N. gruberi using the specific inducer rapamycin. The formation of autophagy vacuoles in treated trophozoites was observed by ultrastructural analysis, and real time quantitative PCR demonstrated overexpression of the atg8 gene. In addition, we detected an increase in the vacuolar acidification of treated amoebae using the LysoTracker. Finally, confocal microscopy was utilized to identify Atg8 protein signal in the cytoplasm of N. gruberi trophozoites induced with rapamycin and even in trophozoites induced to encyst. In conclusion, N. gruberi possesses an Atg8 protein homolog that is overexpressed during the autophagic mechanism induced by rapamycin and also during encystation of this free-living amoeba.

In silico data analyses of recombinases GdDMC1A and GdDMC1B from Giardia duodenalis.

Giardia duodenalis is a worldwide protozoa known causing diarrhea in all vertebrates, humans among these. Homologous recombination is a mechanism that provides genomic stability. Two putative recombinases were identified in G. duodenalis genome: GdDMC1A and GdDMC1B. In this article, we describe the identification of conserved domains in GdDMC1A and GdDMC1B, such as: DNA binding domains (Helix-turn-helix motif, loops 1 and 2) and an ATPcap and Walker A and B motifs associated with ATP binding and hydrolysis, phylogenetic analyses among assemblages and three-dimensional structure modeling of these recombinases using bioinformatics tools. Also, experimental data is described about LD50 determination for ionizing radiation in trophozoites of G. duodenalis. Additionally, as recombinases, GdDMC1A and GdDMC1B were used to rescue a defective Saccharomyces cerevisiae Δ rad51 strain under genotoxic conditions and data is described. The data described here are related to the research article entitled "Characterization of recombinase DMC1B and its functional role as Rad51 in DNA damage repair in Giardia duodenalis trophozoites" (Torres-Huerta et al.,) [1].