Biology of the Cell

Fluorescent reporters cover a wide range of applications in both basic and applied research. Whether a study involves microscopic imaging to study (co)-localization of proteins, FRET, biosensing, or quantifying gene expression, fluorophores are attractive reporter candidates due to their relatively straightforward in vivo readout. For microbiological applications, a wide variety of fluorescent proteins with varying excitation and emission wavelengths, brightness levels, and maturation times are available. Careful consideration is required when selecting from this large suite of proteins, especially when choosing multiple fluorophores. This is further complicated in phototrophic organisms, which exhibit strong autofluorescence, especially towards the red part of the spectrum, effectively eliminating common candidates such as mCherry. In this study, the specific properties and performance of a selection of fluorescent proteins are systematically evaluated against the background of photosynthetic pigment-derived autofluorescence in the cyanobacterium Synechocystis sp. PCC 6803. Specific readouts of different combinations of fluorescent proteins are also analyzed using high-throughput methods, namely plate reader fluorescent scans and single-cell flow cytometry to quantify fluorescence. The ultimate goal is to assess each fluorescent protein with regard to: 1.) Its ability to be discerned from cyanobacterial autofluorescence. 2.) Its compatibility with other fluorophores in this context. 3.) Its overall suitability in cyanobacterial research. Several highly suitable fluorescent proteins for use in cyanobacteria are identified, including mTagBFP2, mNeonGreen and mScarlet-I and suitable combinations, covering nearly the whole spectrum of visible light. This study expands the knowledge and toolset for current and future researchers and uncovers a whole spectrum of possibilities for fluorescent protein selection in cyanobacterial cell biology.

Although calmodulin is best known as an intracellular calcium sensor, it also possesses calcium-independent functions in unicellular organisms. This is exemplified by the budding yeast S. cerevisiae calmodulin, which binds its essential targets, the pericentrin-like protein Spc110 and type I and V myosins, without needing calcium. Whether such calcium-independent cellular functions are conserved in other yeasts and vertebrates nevertheless remains an open question. Here, we examined the calcium-independent functions of the fission yeast S. pombe calmodulin Cam1 by measuring its intracellular distribution. Using quantitative fluorescence microscopy, we assessed the intracellular localization of two cam1 mutants, where binding of Ca2+ had been compromised by mutations in their EF hands, compared to the wild type protein. Both Cam1-2V and -3V reduced their localization by 90% to the yeast microtubule-organizing center spindle pole bodies (SPB). In contrast, these two mutants did not affect the myosin-dependent localization to the equatorial division plane and to the cell tips. Replacing the endogenous cam1 with cam1-2V decreased the SPB localization of pericentrin Pcp1 by 69%, without changing the localization of either type V or I myosins. Over-expression of Pcp1 rescued the mitotic defects of cam1-2V cells at the restrictive temperature. Surprisingly, the cytokinesis of this cam1 mutant was largely normal. We concluded that fission yeast calmodulin Cam1 depends on Ca2+to be a component of SPBs, suggesting that calcium plays a critical role in the assembly of SPBs.

Fast cytoplasmic streaming enables extensive chloroplast movements in the giant cells of unicellular, siphonous macroalgae. Here, we studied chloroplast movements in two such algae: the Dasycladalean Acetabularia acetabulum and the Bryopsidales Bryopsis sp.. We hypothesised that chloroplast movements function as a protective avoidance mechanism under excess light, particularly in Bryopsis sp., which lacks capacity for fast induction of photoprotective non-photochemical quenching (NPQ) and state transitions. In addition, we also investigated whether chloroplast movements are involved in responses to wounding and herbivory. The movements were studied by light microscopy, photography and pulse modulated chlorophyll a fluorescence quenching analysis. Chemical inhibitors of actin polymerization and microtubules assembly were used to confirm that the observed effects were active responses controlled by the cytoskeleton. A. acetabulum responded to high light by reversible chloroplast aggregation, probed by macro-imaging; and chemical inhibition of chloroplast movements led to an enhancement of Photosystem II photoinhibition, as probed by the fluorescence parameter FV/FM. No chloroplast movements were observed in Bryopsis sp. in response to high light. In A. acetabulum, wounding caused either by cutting or due to feeding by the sap-sucking sea slug Elysia timida triggered aggregation of chloroplasts within minutes of incurring the damage. Interestingly, the aggregation also occurred in intact cells away from the cutting site. Furthermore, the addition of media collected from the vicinity of cut algae was sufficient to induce chloroplast aggregation in intact algae, suggesting that water-borne cues or signals triggered the aggregation response in A. acetabulum. Bryopsis sp., however, responded to cutting by only local chloroplast aggregation. The relevance of chloroplast movements in protection against both abiotic and biotic stressors in A. acetabulum, and the potential reasons behind the different defence strategies of the algae, are discussed.

Cadmium, being a highly toxic metal, perturbs cellular homeostasis by forming stable complexes with numerous thiol-active proteins, ultimately leading to severe liver and lung damage. Despite its well-documented toxicity, the molecular mechanisms governing cadmium export remain poorly understood. Given the chemical similarity between cadmium and copper, we investigated whether the canonical copper-exporting ATPases, ATP7A and ATP7B participate in cadmium handling. Upon Cd treatment in hepatocytes, ATP7B undergoes trafficking to lysosomes via the retromer complex, as also observed in the case of elevated copper, accompanied by the upregulation of acidic lysosomal populations. In contrast, ATP7A expressed in lung adenocarcinoma cells, though exhibit vesicular redistribution upon Cd exposure, does not mediate lysosomal sequestration, suggesting distinct deployment of late secretory pathways by the two copper ATPases in response to cadmium. We have also observed that ATP7B-/- hepatocytes exhibit increased sensitivity to Cd exposure compared to wild-type cells. Whereas, overexpressing the ATP7B amino-terminal copper-binding domain in bacteria alleviates cadmium-induced stress, indicating its capacity to sequester Cd. Caenorhabditis elegans lacking copper-ATPase cua-1, displayed increased Cd sensitivity, while mutants (glo-1-/-), deficient in lysosome-related organelles (LRO), and (lmp-1-/-), deficient in lysosomal membrane glycoprotein, showed reduced resistance to cadmium toxicity. Treatment of the worm with cadmium increases the abundance of lysosomes marked by elevation in lysosomal biogenesis and functional genes, reinforcing the importance of lysosomal pathways in cadmium detoxification. To summarise, we delineated the non-canonical role of copper ATPases and lysosomes in cadmium-induced cellular toxicity.

During maturation of a Golgi cisterna, multiple vesicular transport pathways recycle resident Golgi proteins. Recycling vesicles are captured by Golgi-associated tethers. To assign individual tethers to specific recycling pathways in Saccharomyces cerevisiae, we examined tether arrival and departure using kinetic mapping, and we examined tether function using an ectopic tether localization assay. Those approaches yielded mutually consistent results. Our analysis focused on two coiled coil golgin tethers and the multi-subunit tether GARP. At an intermediate stage of cisternal maturation, the golgin Sgm1 tethers proteins that follow an intra-Golgi recycling pathway dependent on COPI. At a late stage of cisternal maturation, GARP and the golgin Imh1 tether trans- Golgi network (TGN) proteins that follow an intra-Golgi recycling pathway dependent on the AP-1 and Ent5 clathrin adaptors. This involvement of GARP in intra-Golgi recycling had not previously been documented. Imh1 also tethers proteins that recycle from prevacuolar endosome compartments to the TGN. Our findings contribute to an integrated model of Golgi membrane traffic.

Rapid and specific diagnosis of viral and bacterial infections is a significant challenge in medicine and veterinary science, especially in the case of epidemically dangerous pathogens. The African swine fever virus (ASFV), for example, causes annual outbreaks among livestock, resulting in significant economic losses for farmers. DNA aptamers have been identified as a promising tool for point-of-care diagnostics, being highly specific to the target and stable ambient temperatures during storage. In this study, we describe the selection of DNA aptamers targeting the p54 viral protein using a single-round selection process. These aptamers were able to bind both to recombinant protein and inactivated ASFV viral particles. Analysis of the newly generated aptamers revealed a dependence of affinity and thermal stability on Ni2+ content, which was a dopant in the selection process. In some cases, the affinity increased 100 times, and melting temperature increased by 30{degrees}C. We have identify two novel DNA motifs that bound 2-3 Ni2+ or Zn2+ ions.

Heterotrimeric kinesin 2 is the canonical motor protein for anterograde intraflagellar transport (IFT), driving movement of protein complexes towards the tip of cilia and flagella. Here, we show that all members of the Euglenozoa group lack genes for heterotrimeric kinesins and instead possess a variable number of genes for two homodimeric kinesins termed KIN2A and KIN2B. When expressed in vitro, both Trypanosoma brucei kinesins form homodimers and move processively along brain microtubules, KIN2A being faster than KIN2B. Studies in T. brucei and Leishmania mexicana show anterograde and retrograde IFT of both kinesins, with KIN2A travelling throughout the whole length of the flagellum, while KIN2B is concentrated at its base. In the proximal portion of the flagellum, most KIN2B molecules travel without IFT proteins, except for a few particles that are associated with IFT proteins and reach the tip. Surprisingly, the absence of KIN2A has mild effects on IFT and flagellum assembly, whereas KIN2B is essential for both. Investigation of trypanosome flagella deprived of KIN2B revealed that IFT proteins do not access these flagella but that KIN2A can still circulate. These results support a division-of-labour model where KIN2B is responsible for the import of IFT proteins while KIN2A is responsible for most of the anterograde transport.

Eukaryotic cells control their size by coordinating growth and division. Fission yeast divide at a reproducible cell size due to regulated activation of the cyclin-dependent kinase Cdk1. The nuclear concentration of mitotic cyclin Cdc13 increases in a time-dependent manner to promote Cdk1 activation as cells grow. Here, we show that interphase Cdc13 is stable against degradation and nuclear export, but is diluted by cell growth. Low glucose reduced cell growth rate but not time-dependent accumulation of Cdc13. Uncoupling the rates of cell growth and Cdc13 accumulation resulted in higher concentrations of nuclear Cdc13 despite reduced cell size. This change coincided with reduced activating phosphorylation of Cdk1-T167 and occurred dynamically during abrupt changes in glucose concentration. Mathematical modeling and experiments showed that cells maintain size homeostasis under these conditions. In contrast to low glucose, poor nitrogen reduced both cell growth rate and Cdc13 accumulation rate. Therefore, Cdc13 accumulation is independent of cell growth rate but can be altered by nutrient-specific mechanisms.

Phosphatidylinositol (4,5)-bisphosphate (PIP2), the most abundant cellular poly-phosphoinositide (PPI) class of phospholipid, is a central plasma membrane (PM)-associated signaling hub that controls many cellular processes. In this study, we demonstrate that either deletion of the gene encoding actin-binding protein profilin1 (Pfn1) or disruption of Pfn1-actin interaction leads to downregulation of PM PIP2 content in cells. This is also phenocopied when F-actin is depolymerized implying that Pfn1-dependent PIP2 alteration is related to its actin-regulatory function. Phospholipase C (PLC) activity is critical for Pfn1-deficient cells to exhibit the PIP2-related phenotype. These findings, taken together with biochemical signatures of elevated PIP2 hydrolysis (higher baseline PM diacylglycerol-to PIP2 ratio and protein kinase C activity) exhibited by Pfn1-deficient cells, imply that PLC-mediated PIP2 hydrolysis plays a role in Pfn1-dependent regulation of PM PIP2. Furthermore, we unexpectedly found that Pfn1 loss leads to dramatic alterations in several other important forms of lipids, revealing a previously unrecognized role of Pfn1 as a broad regulator of cellular lipid environment that extends beyond PPI control. In conclusion, our study establishes Pfn1 as an important regulator of cellular lipid homeostasis. SUMMARY STATEMENTThis study uncovers a mechanism of how functional loss of Profilin1, a key regulator of actin cytoskeleton, can trigger downregulation of plasma membrane content of PIP2, an important class of phospholipid, in cells.

Abstract: Objective This study aimed to systematically screen for potential candidate biomarkers and identify therapeutic targets associated with gouty arthritis (GA) through integrated analyses of single-cell and bulk RNA sequencing (RNA-seq) data. Methods The single-cell dataset GSE211783 and the bulk RNA-seq dataset GSE160170 were analyzed using a series of bioinformatic approaches, including cell clustering, differential expression analysis, immune cell infiltration assessment, protein-protein interaction network construction, gene set enrichment analysis, as well as drug sensitivity evaluation. To establish an animal model of GA, monosodium urate crystals were injected intra-articularly into experimental mice. Joint swelling was evaluated, and morphological changes in joint tissues were analyzed through hematoxylin-eosin staining. The presence of TREM1-positive cells was detected by immunohistochemistry and the level of TREM1 protein expression in joint tissues were assessed by Western blotting. Results We identified 102 differentially expressed genes (DEGs) and 14 signaling pathways associated with GA. The PPI network revealed 25 hub genes, of which 17 (including TREM1, TNF, PTGS2, and NLRP3) were highly expressed and 8 (including FCGR3B and CXCR6) showed low expression in the GA samples. These genes correlated significantly with the infiltration levels of macrophages. Among the hub genes, TREM1 was selected for further validation because it correlated significantly with all 14 differential pathways. In animal experiments, GA mice developed marked joint swelling and inflammatory tissue injury, along with a significant increase in TREM1-positive cells and TREM1 protein expression. Conclusion Integrative analysis of single-cell and bulk RNA-seq data identified 102 GA-related DEGs and 14 key pathways, from which 25 hub genes were screened. TREM1 is significantly upregulated in GA and may be linked to macrophage function, providing new insights into biomarker and therapeutic target discovery for GA.

Cell size in a proliferating cell population generally varies over a limited range ([~]2-4-fold). Within such populations, organelle content increases with cell size maintaining a relatively constant organelle density (amount per cell volume). However, cells of different types can differ greatly in cell size as well as in organelle composition. In such cases, it is often unclear to what degree, if any, the differences in organelle composition are due to the difference in cell size. In principle, this issue could be resolved by examining situations where a proliferating population of cells of the same cell type exhibit much greater size variation. Here we characterize how organelle content scales with cell volume in the polymorphic fungus, A. pullulans, whose proliferating cells span a [~]100-fold size range. We find that mitochondria and ER content increases in proportion to cell volume, while this is not the case for vacuoles and peroxisomes. Thus, organelle composition is affected by cell size in this system.

Along with the membrane potential and respiration, mitochondrial matrix volume is a critical parameter that determines mitochondrial function. Mitochondria undergo constant changes in matrix volume and cristae dynamics, and in processes that are critical for normal metabolic rates and pathophysiological responses. Changes in matrix volume cannot be easily measured by conventional fluorescence imaging techniques due to the size of the sub-organellar structures, which are below resolution. This challenge was successfully resolved in studies of isolated mitochondria with the use of scattered light. Here we use dark-field imaging, which relies on scattered light contrast, to measure matrix volume dynamics in living cells. We demonstrate that mitochondrial volume changes can be easily detected as changes in intensity of the scattered light following matrix volume modulation with K+ ionophores or by onset of the permeability transition. Specifically, we found that stimulation of K+ influx leads to increase of mitochondrial matrix volume while stimulation of K+ efflux leads to matrix shrinkage, and that activation of the permeability transition leads to high-amplitude mitochondrial swelling in wild-type but not in cells lacking subunit c of ATP synthase. These results directly demonstrate the dynamic nature of mitochondrial matrix volume and its link to physiological and pathological ion transport.

A proteomic analysis of Ixodes scapularis nymph saliva identified 252 proteins, including six tubular lipid-binding proteins (TULIPs). Comparing nymphs fed on mice that were uninfected or infected with Borrelia burgdorferi, twelve salivary proteins showed significant differences in the amounts detected, including XP_040079658.2, which we refer to as TULIP2. Considering the known immunity-related functions of some TULIPs, we expressed and purified TULIP2 from Escherichia coli and analyzed its interaction with B. burgdorferi lipids. The purification of TULIP2 from E. coli presented many obstacles, due to insolubility, which is consistent with previous reports from studies of other TULIP family members. The binding results showed specificity for B. burgdorferi lipids, with evidence for cholesteryl {beta}-galactoside as a major binding target. Molecular modeling of TULIP2 did not show any strong lipid binding sites. We used molecular dynamics simulation of TULIP2 to explore its conformational landscape by thermal unfolding. The earliest unfolding intermediate opened a hydrophobic pocket to which cholesteryl {beta}-galactoside was predicted to bind strongly. We propose that a specific lipid bilayer interaction with TULIP2 triggers the opening of the ligand-binding site.

Chlamydomonas reinhardtii is a model green alga extensively used to study photosynthesis and cilia using molecular biology and genetics. Electroporation is a very common technique to transform DNA into the nuclear genome, which is essential to generate mutant collections and express transgenes. Here, we describe a simple, fast, and efficient protocol to transform strains with an intact cell wall. It achieves a good transformation efficiency without cell wall digestion or use of commercial kits and is compatible with the widely available Gene Pulser electroporation system. Key featuresO_LIHigh transformation efficiency of Chlamydomonas reinhardtii strains with an intact cell wall. C_LIO_LIFaster than currently available electroporation protocols. C_LI

Conventional semen cryopreservation involves equilibration at 4{degrees}C and optimum freezing rates. We hypothesized that a cholesterol-based semen extender obviates the need for equilibration, minimizing total processing time for semen cryopreservation. Experiments were conducted to determine the effects of semen extender (egg yolk- or cholesterol-based) and freezing method (routine or fast) on post-thaw sperm characteristics and fertility of beef and bison semen. In Experiment 1, beef semen diluted in tris-egg yolk-glycerol (TEYG) or cholesterol-cyclodextrin tris-glycerol (CCTG) extender underwent routine or fast freezing method. Cholesterol from animal and plant origins were compared. The routine method included 90-min equilibration at 4{degrees}C and routine freezing (RE-RF, total time 97 min) whereas the fast method included no equilibration and fast freezing (NE-FF, total time 14 min). Post-thaw sperm quality was assessed by CASA, and in vitro fertilization. Post-thaw sperm motility was not affected by the origin of cholesterol (animal or plant), but was lowest in the TEYG NE-FF group (24% vs 43-51%, P < 0.05). In vitro cleavage and blastocyst development rates did not differ between RE-RF and NE-FF groups. In Experiment 2, bison semen was diluted in TEYG or plant-CCTG extender and frozen as in Experiment 1. Post-thaw sperm motility was lowest in the TEYG NE-FF group (10% vs 39-51%, P < 0.05). In Experiment 3, beef semen diluted in TEYG or plant-CCTG extender underwent either a routine (RE-RF) or modified freezing (NE-RF, total time 25 min) method. Post-thaw sperm characteristics did not differ between extenders but were greater using routine freezing (RE-RF) compared to the modified method of freezing (NE-RF). Pregnancy rates were similar between extenders (TEYG vs plant-CCTG) using the modified freezing method without equilibration and insemination at 72 h after progesterone device removal. In conclusion, beef and bison semen diluted in cholesterol-based extender may be cryopreserved without equilibration.

ObjectiveRecently, alternatives to animal testing, such as new approach methodologies, are being developed in the orthopedic research field; animal models still provide valuable insights into the pathogenesis of knee osteoarthritis (OA). However, commonly used models develop OA much more rapidly and severely than those observed in human patients. We aimed to develop a novel murine model that closely mimics the slow progression of human OA with posterior Cruciate ligament (PCL) rupture. Design12-week-old C57BL/6 mice were induced to PCL-rupture (PCL-R) by manually applying an external tibial posterior translation force. We analyzed joint kinematics, histological observations, and bone structure to confirm the absence of concurrent injury on day 0. Then, joint stability and the pathophysiological progression of knee OA were analyzed at 8, 16, and 34 weeks post-PCL-R. The destabilized medial meniscus (DMM) model was also analyzed to compare the OA progression. ResultsNon-invasive PCL-R intervention induced the complete rupture in the central region of PCL without concurrent injury. The PCL-R group showed larger posterior tibial deviation than the INTACT (P=0.008). Regarding the range of motion in the PCL-R group, there was no limitation in range of motion on day 0, but extension limitations occurred at weeks 16 and 34 weeks. Histologically, articular cartilage degeneration in PCL-R was milder than DMM. In the subchondral bone, micro-CT reconstruction images indicated that, compared with the INTACT group, the DMM group observed progressive subchondral bone formation from 16 weeks post-surgery. In contrast, the PCLR group maintained the subchondral bone structure even at 34 weeks. ConclusionsPCL-R model induced mild abnormal mechanical stress depending on posterior instability, and cartilage degeneration occurred more slowly in this model than in DMM models.

Bdelloid rotifers are known to survive desiccation and high doses of ionizing radiation. This extreme resistance is notably due to their capacity to cope with numerous DNA double-strand breaks (DSBs). Genes encoding key components of the non-homologous end joining (NHEJ) DNA repair pathway are strongly upregulated in the bdelloid rotifer Adineta vaga following exposure to ionizing radiation. Considering the notably high doses tolerated by these organisms, their capacity to efficiently restore genome integrity is particularly striking. Although NHEJ is generally regarded as less accurate than homologous recombination (HR), the absence of major genomic rearrangements in the descendants of irradiated rotifers suggests that DNA repair occurs with high fidelity. Terwagne et al. recently reported a delayed repair in germline nuclei, occurring during oocyte development when homologous chromosomes pair, thereby enabling template-based repair through HR. In this study, we established an in situ hybridization approach on A. vaga cryosections to investigate the spatial and temporal expression of key actors involved in NHEJ, HR, and Base excision repair (BER) pathways in somatic and germline tissues. We show that NHEJ (KU80) and BER-related genes (PARPs) as well as A. vaga Ligase E (putatively involved in DNA repair) are expressed early after radiation exposure in the somatic syncytium. In contrast, HR-related genes (Rad51: two paralogs, Rad54), as well as PCNA (involved in DNA replication, NER, BER, HR) are expressed later in maturing oocytes, indicating the activation of a delayed homologous recombination repair pathway in germline nuclei. Nurse cells, which express genes associated with both HR and NHEJ pathways, may rely on both mechanisms for their own DNA repair while also supplying mRNAs to the maturing oocyte. Our results provide new evidence for a differential regulation of DNA DSB repair pathways between soma and germline in bdelloids, with NHEJ predominating in somatic tissues and HR in the germline of A. vaga. O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=200 SRC="FIGDIR/small/722046v1_ufig1.gif" ALT="Figure 1"> View larger version (35K): org.highwire.dtl.DTLVardef@3b1f3borg.highwire.dtl.DTLVardef@17f5eb5org.highwire.dtl.DTLVardef@122ef14org.highwire.dtl.DTLVardef@7e4413_HPS_FORMAT_FIGEXP M_FIG O_FLOATNOAbstract Figure:C_FLOATNO Summary of in situ hybridization results: genes coding for actors of NHEJ are expressed in the somatic nuclei and in the nurse nuclei of Adineta vaga individuals 2.5 hours post X-rays radiation, while genes coding for HR actors and PCNA (involved in multiple pathways including DNA replication and DNA repair: NER, BER, MR, HR) are expressed in the nurse nuclei 2.5 hours post radiation, and later in the maturing oocyte during oogenesis and in the laid eggs. Genes coding for actors highly expressed post-radiation, involved in the BER pathway appear to be only expressed in the somatic syncytium 2.5 hours post radiation, as well as the gene coding for the Ligase E, likely involved in DNA repair. C_FIG

The prevalent transcriptional repressor NrdR binds to highly conserved prokaryotic sequences in the promoter regions of operons encoding the essential enzyme ribonucleotide reductase. The NrdR binding sites consist of two partially palindromic 16 bp sequences (NrdR boxes) separated by a 15-16 bp linker sequence. We have assessed the requirement of both boxes for binding, the propensity of different NrdRs to bind to heterologous binding sites, and that the linker sequence is only limited to length and not sequence conservation. As we have observed several deviations from the conserved sequences of the NrdR boxes, we here test the conservation requirements of individual basepairs in the NrdR boxes using a synthetic DNA fragment (Synt DNA) to which the NrdR proteins from the actinomycete Streptomyces coelicolor and the gammaproteobacterium Escherichia coli bind equally well as to their homologous binding sites. By introducing isolated mutations to Synt DNA and testing the binding capacity of NrdR from S. coelicolor and E. coli we expand our understanding of what criteria are needed to build a functional binding site for the NrdR repressor.

Centrosome dysfunction is linked to developmental disorders affecting brain and body size, including microcephaly and primordial dwarfism. However, the cellular mechanisms underlying these rare conditions remain poorly understood. In this study, we investigate a rare variant of the centrosome-associated protein Pericentrin, which was discovered in a single family with Majewski/microcephalic osteodysplastic primordial dwarfism type II (MOPD II). Unlike the majority of pathogenic PCNT variants that cause severe protein truncation, the p.Lys3154del variant ({Delta}K3154) involves a single amino acid deletion in the proteins only conserved functional domain, providing a unique opportunity to explore PCNT function in MOPD II. To model PCNT{Delta}K3154, we examined the effects of Drosophila Pericentrin-like protein (PLP) carrying an orthologous deletion (Plp{Delta}R). Our results show that plp{Delta}R animals exhibit smaller tissues that recapitulate MOPD II phenotypes. Behavioral assays revealed defects in climbing and mechanosensation, suggesting impaired sensory cilia function. We also found that Plp{Delta}R cells exhibit accelerated mitosis, increased apoptosis, and reduced pericentriolar material recruitment. In silico structural modeling, yeast two-hybrid, and co-immunoprecipitation experiments show that Plp{Delta}R produces a protein that disrupts PLP dimerization and PLP interaction with Asterless, another centrosome protein. Overall, modeling the human MOPD II patient variant PCNT{Delta}K3154 in Drosophila reveals how a single amino acid deletion affects biological processes from the molecular level to the organismal level. Our work offers new insights into the defective cellular mechanisms underlying MOPD II in patients with the PCNT{Delta}K3154 variant, potentially linking the etiology of the disease in these individuals to the loss of a single protein-protein interaction.

The Rho family of small GTPases plays a critical role in regulating actin cytoskeleton dynamics during endocytic processes in E. histolytica, including phagocytosis, pinocytosis, and trogocytosis. These proteins act as molecular switches, transitioning between inactive GDP-bound and active GTP-bound states, with guanine nucleotide exchange factors (GEFs) catalyzing this transition. Among the GEFs, EhFP10--a FYVE-domain-containing protein harbouring Dbl homology (DH) and pleckstrin homology (PH) domain was observed in phagocytosis along with seven functionally characterized Rho GTPases (EhRho1, EhRho2, EhRho4, EhRho5, EhRho6, EhRho8, and EhRho13). To study the specificity of FP10, a combination of GEF activity, binding affinity, and molecular dynamics simulations was used to characterize the interactions between EhFP10 and seven Rho GTPases systematically. The results revealed EhRho2 as the most specific and high-affinity interactor of EhFP10, with the highest nucleotide exchange rate and lowest dissociation constant (KD = 0.58 {micro}M). Structural modeling, sequence alignment, and interaction mapping further demonstrated that EhRho2 retains critical contact residues--such as Glu33, Arg4, and Leu69--that are variably absent in other isoforms, correlating with decreased GEF responsiveness. Molecular dynamics simulations and cross-correlation analyses supported the presence of a stable and coordinated interaction interface in the EhFP10-EhRho2 complex, distinguishing it from less active complexes. These findings indicate a highly selective GEF-GTPase module in E. histolytica, analogous to those in higher eukaryotes. The results uncover a potential regulatory mechanism specific to pathogenic amoebae and present EhFP10-EhRho2 as a novel therapeutic target for disrupting cytoskeleton-mediated processes crucial to virulence.