Aberrant Morphology Research Articles

Ovarian premature aging: VIP as key regulator of fibro-inflammation and foamy macrophages generation.

Ovarian aging is associated with fibro-inflammation, contributing to the decline in oocyte count and quality. Given the immunomodulatory properties of the vasoactive intestinal peptide (VIP) in the reproductive tract, we investigated its role in maintaining ovarian immune homeostasis and preventing premature aging. We evaluated young VIP knockout (KO) mice, comparing them to young wild type (WT) females, for signs of premature aging. Histological staining revealed aberrant ovarian morphology in VIP KO mice, characterized by increased atretic follicles and decreased ovarian reserve compared to WT controls. Moreover, VIP KO ovaries showed reduced vascularization, increased collagen deposition and elevated ROS and IL-1β levels. Foamy macrophages were significantly predominant, indicating premature aging in young VIP KO ovaries. To determine potential mechanisms behind these pathogenic changes, we conditioned peritoneal macrophages from young WT or VIP KO mice in vitro with ovarian-conditioned media from young WT or VIP KO mice to mimic the respective ovarian microenvironment. When WT or VIP KO peritoneal macrophages were conditioned with ovarian media from their respective genotypes, lipid droplet accumulation increased compared to control medium. In cross-genotype experiments, WT macrophages conditioned with media from VIP KO ovaries selectively accumulated higher levels of lipid droplets, whereas no differences were observed in VIP KO macrophages conditioned with WT ovarian media. This suggests that VIP KO macrophages are uniquely sensitized to the inflammatory environment of VIP KO ovaries, implicating both ovarian factors and macrophage status. These findings highlight the role of VIP in preventing fibro-inflammation, thereby preserving ovarian health and preventing premature aging.

Morphokinetic Analyses of Fishing Cat-Domestic Cat Interspecies Somatic Cell Nuclear Transfer Embryos Through A Time-Lapse System.

A time-lapse live embryo monitoring system provides a powerful approach to recording dynamic developmental events of cultured embryos in detail. By obtaining continuous short-interval images, blastocyst formation can be predicted and embryos can be selected. The objective of this study was to investigate the morphokinetic parameters of fishing cat-domestic cat interspecies somatic cell nuclear transfer (iSCNT) embryos from one-cell to blastocyst stages, and in particular, the cleavage patterns of the first division in iSCNT and IVF embryos, as these play a central role in euploidy. Domestic cat in vitro fertilization (IVF) embryos were set up as controls. The results show that morula and blastocyst development rates were significantly lower in the iSCNT embryos compared to their IVF counterparts. All earlier time points of embryonic development before the onset of blastulation in the iSCNT embryos were significantly delayed when compared with their IVF counterparts. In iSCNT, normal embryos (defined as those that developed to the blastocyst stage) took a longer time to reach the morula stage, and these morulas were more likely to undergo compaction, compared to their arrested embryo counterparts. Direct cleavage in the first division is a morphological aberration, and was seen with greater prevalence in iSCNT embryos than control IVF embryos; these aberrant embryos displayed a significantly lower blastocyst development rate than embryos that had undergone normal cleavage. In conclusion, the morphokinetic parameters of fishing cat-domestic cat iSCNT embryos at early stages could be used to predict their potential for development to the blastocyst stage. A time-lapse imaging system is potentially a powerful tool for selecting early embryos with developmental potential for transfer, and hence, for improving feline iSCNT efficiency.

Synergistically effects of n-3 PUFA and B vitamins prevent diabetic cognitive dysfunction through promoting TET2-mediated active DNA demethylation.

Diabetic cognitive dysfunction (DCD) refers to the cognitive impairment observed in individuals with diabetes. Epidemiological studies have suggested that supplementation with n-3 polyunsaturated fatty acid (PUFA) or B vitamins may prevent the development of diabetic complications. Post hoc studies indicate a potential synergistic effect of n-3 PUFA and B vitamins in preventing cognitive impairment. However, the precise effect and underlying mechanism of this combination on DCD remain unclear. In case-control study, we compared fatty acid composition of erythrocyte membrane and serum homocysteine levels between diabetic individuals with and without DCD. We found that insufficient levels of n-3 PUFA, along with elevated serum homocysteine, significantly increase the risk of developing DCD. Treatment with a combination of fish oil, folate, and vitamin B12 improved cognitive impairment and aberrant neuronal morphology in streptozotocin-induced DCD mice. Folic acid and vitamin B12 enhanced the efficiency of exogenous docosahexaenoic acid (DHA) transportation to the brain by preventing the accumulation of homocysteine and S-adenosylhomocysteine, thereby inhibiting neuronal apoptosis in diabetic brains. Furthermore, folic acid and vitamin B12 supplementation can provide sufficient 5-methylcytosine for diabetic brains by promoting DNA methylation, while increased DHA levels maintain TET-mediated active DNA demethylation in diabetic brains through enhancing TET2 function. Overall, our study provides novel insights into molecular mechanisms underlying the synergistic preventive effects of the combined supplementation with fish oil, folic acid and vitamin B12 on DCD, suggests that combining n-3 PUFA and B vitamins could be a promising strategy for preventing DCD among individuals with diabetes.

Neuronal effect of 0.3 % DMSO and the synergism between 0.3 % DMSO and loss function of UCH-L1 on Drosophila melanogaster model.

Dimethyl sulfoxide (DMSO) is a polar aprotic solvent which is widely used in biological and medical studies and as a vehicle for pharmacological therapy. DMSO from 0.1 % to 0.5 %, particularly 0.3 % is commonly used as solvent to dissolve compounds when testing their effect on living cell, tissues including nerve cell. However, scientific data on the effects of DMSO on nervous system is limited. Here, we present our data of case study on investigation the effects of DMSO at 0.3 % concentration on nerve cell of Drosophila melanogaster model. We found that 0.3 % DMSO concentration had affected on the active zone and glutamate receptor. Notably, this study also revealed the synergistic effect of 0.3 % DMSO and loss function of dUCH (the homolog of Ubiquitin Carboxyl terminal Hydrolase -L1, UCH-L1 in D. melanogaster). This combination caused more serious abnormalities in synapse structure, particularly number of boutons on Neuromuscular Junction, NMJ. Furthermore, 0.3 % DMSO reduced the amount of ubiquitinylated protein aggregates in the indirect flight muscle of both normal and genectic defect fly model. Taken together, data in this sytudy indicated that 0.3 % DMSO caused the aberrant morphology of the synaptic structure and decreased the number of ubiquitinylated proteins in the indirect flight muscle of Drosophila. The data from the study contributed new evidence of the effects of DMSO on the nervous system. Signigicantly, this study revealed that DMSO affected on neuron cell at low concentration which widely used as pharmacological solvent.

A tripartite transcriptional module regulates protoderm specification during embryogenesis in Arabidopsis.

Protoderm formation is a crucial step in early embryo patterning in plants, separating the precursors of the epidermis and the inner tissues. Although key regulators such as ARABIDOPSIS THALIANA MERISTEM LAYER1 (ATML1) and PROTODERMAL FACTOR2 (PDF2) have been identified in the model plant Arabidopsis thaliana, the genetic pathways controlling protoderm specification remain largely unexplored. Here, we combined genetic, cytological, and molecular approaches to investigate the regulatory mechanisms of protoderm specification in Arabidopsis thaliana. We report a novel role of the β-importin KETCH1 in protoderm specification. KETCH1 loss-of-function leads to aberrant protoderm cell morphology and absent ATML1 transcription in embryos. We further demonstrate that KETCH1 directly interacts with an RNA Polymerase II (Pol-II) cofactor JANUS, mediating its nuclear accumulation. Furthermore, JANUS directly interacts with the WUS HOMEOBOX2 (WOX2) protein, which is critical for WOX2-activated ATML1 expression. Consequently, JANUS, KETCH1, and WOX2 loss-of-function results in similar protoderm defects. Our results identify the tripartite KETCH1/JANUS/WOX2 transcriptional module as a novel regulatory axis in Arabidopsis protoderm specification.

TAT-1, a phosphatidylserine flippase, affects molting and regulates membrane trafficking in the epidermis of C. elegans.

Membrane trafficking is a conserved process required for import, export, movement, and distribution of proteins and other macromolecules within cells. The Caenorhabditis elegans NIMA-related kinases NEKL-2 (human NEK8/9) and NEKL-3 (human NEK6/7) are conserved regulators of membrane trafficking and are required for the completion of molting. Using a genetic approach we identified reduction-of-function mutations in tat-1 that suppress nekl-associated molting defects. tat-1 encodes the C. elegans ortholog of mammalian ATP8A1/2, a phosphatidylserine (PS) flippase that promotes the asymmetric distribution of PS on the cytosolic leaflet of lipid membrane bilayers. CHAT-1 (human CDC50), a conserved chaperone, was required for the correct localization of TAT-1, and chat-1 inhibition strongly suppressed nekl defects. Using a PS sensor, we found that TAT-1 was required for the normal localization of PS at apical endosomes and that loss of TAT-1 led to aberrant endosomal morphologies. Consistent with these data, TAT-1 localized to early endosomes and to recycling endosomes marked with RME-1, the C. elegans ortholog of the human EPS15 homology (EH) domain-containing protein, EHD1. TAT-1, PS biosynthesis, and the PS-binding protein RFIP-2 (human RAB11-FIP2) were all required for the normal localization of RME-1 to apical endosomes. Consistent with these proteins functioning together, inhibition of RFIP-2 or RME-1 led to the partial suppression of nekl molting defects, as did inhibition of PS biosynthesis. We propose that TAT-1 flippase activity, in conjunction with RFIP-2, promotes the recruitment of RME-1 to apical recycling endosomes and that inhibition of TAT-1-RFIP-2-RME-1 can compensate for a reduction in NEKL activities.

Unusual bot fly larva removed from the scalp of a returning traveler.

An aberrant bot fly specimen was removed from the scalp of a patient 3wk after returning from Belize. The specimen showed little resemblance to the typical human bot fly larva, Dermatobia hominis, prompting a molecular identification using cytochrome oxidase I and II (COI and COII, respectively) mitochondrial DNA sequence regions. A BLAST search was subsequently performed, and both our COI and COII amplicon sequences showed 99-100% match with Dermatobia hominis, despite the specimen's clearly aberrant morphology. These findings suggest there is much wider variation in Dermatobia larval morphology than previously known or perhaps that there are new or cryptic species within this group.

Anacyclus pyrethrum enhances fertility in cadmium-intoxicated male rats by improving sperm functions

BackgroundEnvironmental pollutants, particularly heavy metals, have been frequently connected to male infertility. Cadmium was previously shown to reduce male fertility by causing oxidative stress. Anacyclus pyrethrum is a well-known medicinal plant. Most of its parts, notably the roots, have excellent antioxidant and anti-inflammatory properties. The present study investigated the potential ability of Anacyclus pyrethrum to protect male rats against cadmium reproductive toxicity.MethodsTwenty-eight adult Wistar male rats (8 weeks old) weighing (170-200g) were randomly divided into four groups (n = 7): group (1) the control, group (2) was orally administrated with Anacyclus pyrethrum extract (100mg/kg) for 56 consecutive days, group (3) received a single intraperitoneal (IP) injection of cadmium chloride (1mg/kg), and group (4) received a single IP dose of CdCl2 followed by 8 weeks of oral Anacyclus extract treatment.ResultsCadmium Cd toxicity resulted in a significant decrease in the concentration of antioxidant enzymes (superoxide dismutase SOD and glutathione peroxidase GPx) in the semen coupled with a significant rise in malondialdehyde MDA level. Consequently, sperm analysis parameters were significantly affected showing decreased motility, viability, concentration and increased morphological aberrations. DNA fragmentation was also detected in the sperms of rats exposed to Cd using comet assay. Serum levels of testosterone T, follicle stimulating hormone FSH, and luteinizing hormone LH were significantly decreased. The mRNA expression levels of sex hormone receptors (FSHR, LHR and AR) in the testis of the Cd exposed rats were significantly decreased. Expression levels of Bax and Bcl2 genes in the sperms of Cd intoxicated rats were also affected shifting the Bax/Bcl2 ratio towards the induction of apoptosis. Co-treatment with the Anacyclus pyrethrum extract restored the oxidative enzymes activities and decreased the formation of lipid peroxidation byproduct, which in turn ameliorated the effect of Cd on sperm parameters, sperm DNA damage, circulating hormone levels, gene expression and apoptosis. These results indicate that Anacyclus pyrethrum could serve as a protective agent against cadmium-induced sperm toxicity.ConclusionTaken together, it can be concluded that the antioxidant activities of Anacyclus pyrethrum restored the semen quality and enhanced fertility in Cd-intoxicated male rats.

Morphological aberration of corneal nerves in hyposecretory dry eye guinea pigs.

Dry eye, a common ocular surface disease associated with tear film instability and corneal impairment, is frequently accompanied by ocular discomfort and pain. Recent research has shown that corneal nerve dysfunction may play a role in certain pathologies of dry eye; however, the details remain unclear. To clarify the aberration in corneal nerves underlying sensory abnormalities, in addition to corneal impairment in dry eye, we examined the morphological alterations of nerve fibers in the corneas excised from guinea pigs with dry eye, where the lacrimal glands were surgically excised. Guinea pigs with dry eye exhibited reduced tear volume, increased spontaneous blink frequency, and corneal epithelial damage. Simultaneously, the subbasal nerve plexus in the cornea visualized using an anti-tubulin βIII antibody partially outgrew and became convoluted. The morphology of peptidergic nerves containing calcitonin gene-related peptide, which may function as a polymodal nociceptor, was also altered. These results indicate that guinea pigs with excised lacrimal glands can serve as useful tools for investigating the neuronal mechanisms underlying corneal pathology in dry eyes. Additionally, chronic tear deficiency may considerably alter nerve structure, including peptidergic nerves in the cornea, accompanied by epithelial damage and increased blink frequency.

Synergistic potential of Leu10-teixobactin and cefepime against multidrug-resistant Staphylococcus aureus

Staphylococcus aureus (S. aureus) is a significant Gram-positive opportunistic pathogen behind many debilitating infections. β-lactam antibiotics are conventionally prescribed for treating S. aureus infections. However, the adaptability of S. aureus in evolving resistance to multiple β-lactams contributed to the persistence and spread of infections, exemplified in the emergence of methicillin-resistant S. aureus (MRSA). In the present study, we investigated the efficacies of the synthetic teixobactin analogue, Leu10-teixobactin, combined with the penicillinase-resistant cephalosporin cefepime against MRSA strains. The Leu10-teixobactin and cefepime combination exerted synergism against most strains tested in broth microdilution assay. Time-kill profiles showed that both Leu10-teixobactin and cefepime predominantly exhibited synergistic activity, with > 2.0-log10CFU decrease compared to monotherapy at 24 h. Moreover, biofilm assays revealed a significant inhibition of biofilm production in ATCC™43300 cells treated with sub-MICs of Leu10-teixobactin and cefepime. Subsequent electron microscopy studies showed more extensive damage with the combination therapy compared to monotherapies, including aberrant bacterial morphology, vesicle formation and substantial lysis, indicating combined damage to the cell wall. Quantitative real-time PCR revealed marked perturbation of genes mecA, sarA, atlA, and icaA, substantiating the apparent mode of combined antibacterial action of both antibiotics against peptidoglycan synthesis and initial biofilm production. Hence, the study highlights the prospective utility of the Leu10-teixobactin-cefepime combination in treating MRSA infections via β-lactam potentiation.

An attractor state zone precedes neural crest fate in melanoma initiation.

The field cancerization theory suggests that a group of cells containing oncogenic mutations are predisposed to transformation1, 2. We previously identified single cells in BRAF V600E ;p53 -/- zebrafish that reactivate an embryonic neural crest state before initiating melanoma3-5. Here we show that single cells reactivate the neural crest fate from within large fields of adjacent abnormal melanocytes, which we term the "cancer precursor zone." These cancer precursor zone melanocytes have an aberrant morphology, dysplastic nuclei, and altered gene expression. Using single cell RNA-seq and ATAC-seq, we defined a distinct transcriptional cell attractor state for cancer precursor zones and validated the stage-specific gene expression initiation signatures in human melanoma. We identify the cancer precursor zone driver, ID1, which binds to TCF12 and inhibits downstream targets important for the maintenance of melanocyte morphology and cell cycle control. Examination of patient samples revealed precursor melanocytes expressing ID1, often surrounding invasive melanoma, indicating a role for ID1 in early melanomagenesis. This work reveals a surprising field effect of melanoma initiation in vivo in which tumors arise from within a zone of morphologically distinct, but clinically covert, precursors with altered transcriptional fate. Our studies identify novel targets that could improve early diagnosis and prevention of melanoma.

Decreased Mrpl42 expression exacerbates myocardial ischemia and reperfusion injury by inhibiting mitochondrial translation

Mammalian mitochondrial DNA (mtDNA) encodes a total of 13 proteins, all of which are subunits of enzyme complexes of the oxidative phosphorylation. The mtDNA-encoded protein synthesis depends on the mitochondrial ribosomal proteins (MRPs), which assemble to form a specialized form of ribosome. Some mtDNA-encoded proteins have been reported to be reduced after myocardial ischemic injury. However, the molecular mechanisms responsible for this decrease and whether this decrease is involved in myocardial ischemia/reperfusion (I/R) injury remains unknown. Here, we found that the mtDNA-encoded protein levels were significantly decreased after I/R injury, while the mRNA levels of these genes were either increased or had no significant change. Subsequently, by querying and analyzing public database resources, we found that the expression of many mitochondrial translation-related proteins tended to decrease after myocardial infarction injury, and the reduction in the expression of these proteins was most obvious for Mrpl42. Furthermore, we found that cardiac Mrpl42 knockdown aggravated I/R-induced cardiac contractile dysfunction and cardiomyocyte death, while restoring Mrpl42 expression in the heart reduced I/R injury. Mrpl42 knockdown impaired the translation of mtDNA-encoded genes, ultimately led to aberrations in mitochondrial morphology and respiratory function. In addition, we found that the decrease in the expression of Mrpl42 after I/R injury was caused by the downregulation of Nrf2, which directly regulates Mrpl42 transcription. Our study revealed that ischemic downregulation of Mrpl42 expression and subsequent inhibition of mitochondrial translation contribute to cardiac I/R injury. Targeting Mrpl42 may be a novel therapeutic intervention for cardiac I/R injury and myocardial infarction.

SON-dependent nuclear speckle rejuvenation alleviates proteinopathies.

Current treatments targeting individual protein quality control have limited efficacy in alleviating proteinopathies, highlighting the prerequisite for a common upstream druggable target capable of global proteostasis modulation. Building on our prior research establishing nuclear speckles as a pivotal membrane-less organelle responsible for global proteostasis transcriptional control, we aim to alleviate proteinopathies through nuclear speckle rejuvenation. We identified pyrvinium pamoate as a small-molecule nuclear speckle rejuvenator that enhances protein quality control while suppressing YAP1 signaling via decreasing the surface/interfacial tension of nuclear speckle condensates through interaction with the intrinsically disordered region of nuclear speckle scaffold protein SON. In pre-clinical models, nanomolar pyrvinium pamoate alleviated retina degeneration and reduced tauopathy by promoting autophagy and ubiquitin-proteasome system in a SON-dependent manner without causing cellular stress. Aberrant nuclear speckle morphology, reduced protein quality control and increased YAP1 activity were also observed in human tauopathies. Our study uncovers novel therapeutic targets for tackling protein misfolding disorders within an expanded proteostasis framework encompassing nuclear speckles and YAP1.

EMC1 Is Required for the Sarcoplasmic Reticulum and Mitochondrial Functions in the Drosophila Muscle

EMC1 is part of the endoplasmic reticulum (ER) membrane protein complex, whose functions include the insertion of transmembrane proteins into the ER membrane, ER–mitochondria contact, and lipid exchange. Here, we show that the Drosophila melanogaster EMC1 gene is expressed in the somatic musculature and the protein localizes to the sarcoplasmic reticulum (SR) network. Muscle-specific EMC1 RNAi led to severe motility defects and partial late pupae/early adulthood lethality, phenotypes that are rescued by co-expression with an EMC1 transgene. Motility impairment in EMC1-depleted flies was associated with aberrations in muscle morphology in embryos, larvae, and adults, including tortuous and misaligned fibers with reduced size and weakness. They were also associated with an altered SR network, cytosolic calcium overload, and mitochondrial dysfunction and dysmorphology that impaired membrane potential and oxidative phosphorylation capacity. Genes coding for ER stress sensors, mitochondrial biogenesis/dynamics, and other EMC components showed altered expression and were mostly rescued by the EMC1 transgene expression. In conclusion, EMC1 is required for the SR network’s mitochondrial integrity and influences underlying programs involved in the regulation of muscle mass and shape. We believe our data can contribute to the biology of human diseases caused by EMC1 mutations.

8672 Disrupted Glucocorticoid Receptor Mediated Signalling Causes a Primary Cilia Defect in the Fetal Mouse Renal Tubule

Abstract Disclosure: J. Lao: None. K.L. Short: None. J. Ng: None. D.L. Cottle: None. T.J. Cole: None. Primary cilia are microtubule-based organelles that protrude from cell membranes to mediate diverse developmental signalling pathways and senses extracellular stimuli to maintain tissue homeostasis. We show that glucocorticoid (GC) signalling via the glucocorticoid receptor (GR) is a regulator of normal primary cilia formation in kidney renal tubules. RNA sequencing of whole E18.5 fetal kidney from mice with global deletion of the GR (GR-null) compared to littermate wild-type controls identified significantly reduced mRNA levels of key ciliogenesis-related genes. Further analysis of whole fetal kidney RNA by real-time-qPCR confirmed reduced mRNA levels for the cilia-associated proteins Ccp110 (fold -2.18), Cep97 (fold -1.78), Cep290 (fold -2.91), Kif3a (fold -1.82) and Rpgr (fold -1.90). Confocal microscopy revealed abnormal, stunted primary cilia in renal proximal tubules, collecting ducts and podocytes in GR-null or in renal tubule conditional GR-deleted mice, created using the HoxB7 Cre-driver allele. Primary cilia length was significantly decreased in kidney proximal tubule cells in GR-null mice (5.01 ± 0.11μm) compared with wildtype controls (6.20 ± 0.15μm). Furthermore, scanning electron microscopy of E18.5 GR-null kidney further confirmed aberrant primary cilia morphology in the proximal renal tubules and the absence of an apical brush border. Activation of GR signalling with the synthetic GC dexamethasone in cultured mouse IMCD3 kidney tubule cells significantly increased primary cilia length (2.89 ± 0.04μm) compared to vehicle controls (2.46 ± 0.28μm), an effect blocked by the GR antagonist RU486 (vehicle + RU486: 2.06 ± 0.02μm, dexamethasone + RU486: 2.00 ± 0.02μm). Aurora kinase A (AURKA) is a known regulator of primary cilia formation via the AKT cell signalling pathway and distinct proteins at different stages of the mitotic cell cycle. AURKA protein levels were downregulated in GR-null kidney and in IMCD3 cells which suggest GR regulates AURKA to control the assembly and disassembly of primary cilia. Together, these results demonstrate that GC signalling via the GR is required for normal primary ciliogenesis in the developing renal tubule and suggests that synthetic GR agonists may provide a novel therapeutic option for human ciliopathies such as those observed in forms of polycystic kidney disease. Presentation: 6/2/2024

Soma-to-germline BMP signal is essential for Drosophila spermiogenesis

In the Drosophila testis, developing germ cells are encapsulated by somatic support cells throughout development. Soma-germline interactions are essential for successful spermiogenesis. However, it is still not fully understood what signaling events take place between the soma and the germline. In this study, we found that a Bone Morphogenetic Protein (BMP) ligand, Glass bottom boat (Gbb), secreted from somatic cyst cells (CCs), signals to differentiating germ cells to maintain proper spermiogenesis. Knockdown of Gbb in CCs or the type I BMP receptor Saxophone (Sax) in germ cells leads to a defect in sperm head bundling and decreased fertility. Our Transmission Electron Microscopy (TEM) analyses revealed that the mutant germ cells have aberrant morphology of mitochondria throughout the stages of spermiogenesis and exhibit a defect in nebenkern formation. Elongating spermatids show uncoupled nuclei and elongating mitochondrial derivatives, suggesting that improper mitochondrial development may cause sperm bundling defects. Taken together, we propose a new role of soma-derived BMP signaling, which is essential for spermiogenesis.

Deoxyhypusine synthase deficiency syndrome zebrafish model: aberrant morphology, epileptiform activity, and reduced arborization of inhibitory interneurons

DHPS deficiency syndrome is an ultra-rare neurodevelopmental disorder (NDD) which results from biallelic mutations in the gene encoding the enzyme deoxyhypusine synthase (DHPS). DHPS is essential to synthesize hypusine, a rare amino acid formed by post-translational modification of a conserved lysine in eukaryotic initiation factor 5 A (eIF5A). DHPS deficiency syndrome causes epilepsy, cognitive and motor impairments, and mild facial dysmorphology. In mice, a brain-specific genetic deletion of Dhps at birth impairs eIF5AHYP-dependent mRNA translation. This alters expression of proteins required for neuronal development and function, and phenotypically models features of human DHPS deficiency. We studied the role of DHPS in early brain development using a zebrafish loss-of-function model generated by knockdown of dhps expression with an antisense morpholino oligomer (MO) targeting the exon 2/intron 2 (E2I2) splice site of the dhps pre-mRNA. dhps knockdown embryos exhibited dose-dependent developmental delay and dysmorphology, including microcephaly, axis truncation, and body curvature. In dhps knockdown larvae, electrophysiological analysis showed increased epileptiform activity, and confocal microscopy analysis revealed reduced arborisation of GABAergic neurons. Our findings confirm that hypusination of eIF5A by DHPS is needed for early brain development, and zebrafish with an antisense knockdown of dhps model features of DHPS deficiency syndrome.

Methylmercury chloride inhibits meiotic maturation of mouse oocytes in vitro by disrupting the cytoskeleton

Methylmercury chloride (MMC) is a persistent heavy metal contaminant that can bioaccumulate in humans via the food chain, exerting detrimental effects on health. Nevertheless, the specific influence of MMC on oocyte meiotic maturation has yet to be elucidated. This research demonstrated that MMC exposure during the in vitro cultivation of mouse oocytes did not influence germinal vesicle breakdown but markedly decreased oocyte maturation rates. Subsequent analysis indicated that MMC exposure resulted in aberrant spindle morphology and disorganized chromosome alignment, alongside continuous activation of the spindle assembly checkpoint (SAC). However, MMC exposure didn't alter the localization pattern of microtubule-organizing center-associated proteins. MMC exposure considerably diminished the acetylation level of α-tubulin, signifying reduced microtubule stability. Additionally, MMC exposure disrupted the dynamic alterations of F-actin. MMC exposure didn't affect mitochondrial localization, mitochondrial membrane potential, adenosine triphosphate content or the concentrations of reactive oxygen species. Nonetheless, MMC exposure triggered DNA damage and modified histone modification levels. Consequently, the defects in oocyte maturation induced by MMC exposure can be attributed to impaired cytoskeleton dynamics and DNA damage. This study offers the first comprehensive elucidation of the negative impacts of MMC on oocyte maturation, highlighting the potential reproductive health risks associated with MMC exposure.

Microphthalmia and disrupted retinal development due to a LacZ knock-in/knock-out allele at the Vsx2 locus.

Visual System Homeobox 2 (Vsx2) is a transcription factor expressed in the developing retina that regulates tissue identity, growth, and fate determination. Several mutations in the Vsx2 gene exist in mice, including a spontaneous nonsense mutation and two targeted missense mutations originally identified in humans. Here, we expand the genetic repertoire to include a LacZ reporter allele (Vsx2 LacZ ) designed to express beta-Galactosidase (b-GAL) and simultaneously disrupt Vsx2 function (knock-in/knock-out). The retinal expression pattern of b-GAL is concordant with VSX2, and the mutant allele is recessive. Vsx2 LacZ homozygous mice have congenital bilateral microphthalmia accompanied by defects in retinal development including ectopic expression of non-retinal genes, reduced proliferation, delayed neurogenesis, aberrant tissue morphology, and an absence of bipolar interneurons - all hallmarks of Vsx2 loss-of-function. Unexpectedly, the mutant VSX2 protein is stably expressed, and there are subtle differences in eye size and early retinal neurogenesis when compared to the null mutant, ocular retardation J. The perdurance of the mutant VSX2 protein combined with subtle deviations from the null phenotype leaves open the possibility that Vsx2 LacZ allele is not a complete knock-out. The Vsx2 LacZ allele exhibits loss-of-function characteristics and adds to the genetic toolkit for understanding Vsx2 function.

Abstract A017: Comprehensive evaluation of the therapeutic effects of whole-body hyperthermia for pancreatic ductal adenocarcinoma (PDAC) and the potential synergy with standard-of-care chemotherapeutics

Abstract Whole-body hyperthermia (WBHT) is a promising therapeutic approach that leverages elevated temperatures to enhance cancer treatment efficacy. By inducing controlled hyperthermia in the range of 39-42.5°C, cellular processes are disrupted and cancer cells can be sensitized to standard-of-care chemotherapies. However, the precise cellular and molecular mechanisms by which WBHT exerts its effects are not fully understood. Elucidating these mechanisms is particularly crucial for optimizing treatment protocols and improving outcomes in aggressive malignancies such as pancreatic ductal adenocarcinoma (PDAC). This study explores the impact of WBHT at 41.5°C on the cell cycle and associated molecular pathways in PDAC cells, providing insights into its therapeutic value and potential for combination regimens. PDAC cell lines, BxPC-3 and AsPC-1, were subjected to WBHT at 41.5°C for 1-6 hours and analyzed immediately, 24h and 48h post-WBHT Cell proliferation was assessed using the 5-ethynyl-2'-deoxyuridine (EdU) base-incorporation assay and proliferating cell nuclear antigen (PCNA) staining for immunofluorescence detection. Morphological changes post-WBHT were monitored using confocal fluorescence microscopy. Total RNA was extracted and sequenced using the Illumina platform. An in-house pipeline was used for QC, alignment and differential expression analysis. Enrichment analysis was performed to identify affected biological processes and pathways. In vivo experiments employed the chorioallantois membrane (CAM) assay per protocol published in STAR protocols. WBHT at 41.5°C significantly disrupted cell cycle progression in PDAC cell lines. The EdU incorporation assay revealed a dose-dependent decrease in DNA synthesis during and following WBHT, indicating cell cycle arrest in the S-phase. Decreases in Ki67, cyclin B1 and PCNA intensities further confirmed this reduction in cell proliferation. Moreover, cells showed notable signs of cellular and mitotic stress, such as the formation of multi-nucleated giant cells, aberrant metaphase morphology and micronuclei. Bulk RNA-seq confirmed alterations in gene expression profiles relating to the cell cycle immediately after HT exposure. Genes associated with the E2F targets and G2/M checkpoint pathways were negatively enriched, whereas genes involved in the Hallmark apoptosis pathway were positively enriched. Preliminary data from in ovo CAM experiments showed a significant inhibitory effect of WBHT monotherapy on growth of BxPC-3 tumors. Our data show that WBHT severely disrupts the cell cycle at the S- and M-phases, via multiple pathways involved in cell proliferation and apoptosis. These cancer hallmarks are targeted by conventional chemotherapeutics, paving the way for combination therapy as one-two punch cancer treatments. The synergy between WBHT with cisplatin and oxaliplatin, but also with gemcitabine and 5-fluorouracil (5-FU) could be optimized based on the improved understanding of the WBHT effects over time, in terms of WBHT duration, sequence of WBHT and chemo and the exact treatment schedule. Citation Format: Robin Colenbier, Tine Logghe, Gaëlle Boulet, Johannes Bogers, Jean-Pierre Timmermans. Comprehensive evaluation of the therapeutic effects of whole-body hyperthermia for pancreatic ductal adenocarcinoma (PDAC) and the potential synergy with standard-of-care chemotherapeutics [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr A017.