A Library of Aspergillus niger Chassis Strains for Morphology Engineering Connects Strain Fitness and Filamentous Growth With Submerged Macromorphology

Submerged fermentation using filamentous fungal cell factories is used to produce a diverse portfolio of useful molecules, including food, medicines, enzymes, and platform chemicals. Depending on strain background and abiotic culture conditions, different macromorphologies are formed during fermentation, ranging from dispersed hyphal fragments to approximately spherical pellets several millimetres in diameter. These macromorphologies are known to have a critical impact on product titres and rheological performance of the bioreactor. Pilot productivity screens in different macromorphological contexts is technically challenging, time consuming, and thus a significant limitation to achieving maximum product titres. To address this bottleneck, we developed a library of conditional expression mutants in the organic, protein, and secondary metabolite cell factory Aspergillus niger. Thirteen morphology-associated genes transcribed during fermentation were placed via CRISPR-Cas9 under control of a synthetic Tet-on gene switch. Quantitative analysis of submerged growth reveals that these strains have distinct and titratable macromorphologies for use as chassis during strain engineering programs. We also used this library as a tool to quantify how pellet formation is connected with strain fitness and filamentous growth. Using multiple linear regression modelling, we predict that pellet formation is dependent largely on strain fitness, whereas pellet Euclidian parameters depend on fitness and hyphal branching. Finally, we have shown that conditional expression of the putative kinase encoding gene pkh2 can decouple fitness, dry weight, pellet macromorphology, and culture heterogeneity. We hypothesize that further analysis of this gene product and the cell wall integrity pathway in which it is embedded will enable more precise engineering of A. niger macromorphology in future.

A Conditional Glutamatergic Synaptic Vesicle Marker for Drosophila

Glutamate is a principal neurotransmitter used extensively by the nervous systems of all vertebrate and invertebrate animals. It is primarily an excitatory neurotransmitter that has been implicated in nervous system development as well as a myriad of brain functions from the simple transmission of information between neurons to more complex aspects of nervous system function including synaptic plasticity, learning, and memory. Identification of glutamatergic neurons and their sites of glutamate release are thus essential for understanding the mechanisms of neural circuit function and how information is processed to generate behavior. Here we describe and characterize smFLAG-vGlut, a conditional marker of glutamatergic synaptic vesicles for the Drosophila model system. smFLAG-vGlut is validated for functionality, conditional expression, and specificity for glutamatergic neurons and synaptic vesicles. The utility of smFLAG-vGlut is demonstrated by glutamatergic neurotransmitter phenotyping of 26 different central complex neuron types of which nine were established to be glutamatergic. This illumination of glutamate neurotransmitter usage will enhance the modeling of central complex neural circuitry and thereby our understanding of information processing by this region of the fly brain. The use of smFLAG for glutamatergic neurotransmitter phenotyping and identification of glutamate release sites can be extended to any Drosophila neuron(s) represented by a binary transcription system driver.

Increasing NADPH impairs fungal H2O2 resistance by perturbing transcriptional regulation of peroxiredoxin

NADPH provides the reducing power for decomposition of reactive oxygen species (ROS), making it an indispensable part during ROS defense. It remains uncertain, however, if living cells respond to the ROS challenge with an elevated intracellular NADPH level or a more complex NADPH-mediated manner. Herein, we employed a model fungus Aspergillus nidulans to probe this issue. A conditional expression of glucose-6-phosphate dehydrogenase (G6PD)-strain was constructed to manipulate intracellular NADPH levels. As expected, turning down the cellular NADPH concentration drastically lowered the ROS response of the strain; it was interesting to note that increasing NADPH levels also impaired fungal H2O2 resistance. Further analysis showed that excess NADPH promoted the assembly of the CCAAT-binding factor AnCF, which in turn suppressed NapA, a transcriptional activator of PrxA (the key NADPH-dependent ROS scavenger), leading to low antioxidant ability. In natural cell response to oxidative stress, we noticed that the intracellular NADPH level fluctuated “down then up” in the presence of H2O2. This might be the result of a co-action of the PrxA-dependent NADPH consumption and NADPH-dependent feedback of G6PD. The fluctuation of NADPH is well correlated to the formation of AnCF assembly and expression of NapA, thus modulating the ROS defense. Our research elucidated how A. nidulans precisely controls NADPH levels for ROS defense. Graphical Abstract

Transcriptional and post-transcriptional regulation of young genes in plants

New genes continuously emerge from non-coding DNA or by diverging from existing genes, but most of them are rapidly lost and only a few become fixed within the population. We hypothesized that young genes are subject to transcriptional and post-transcriptional regulation to limit their expression and minimize their exposure to purifying selection. We found that young genes in rice have relatively low expression levels, which can be attributed to distal enhancers, and closed chromatin conformation at their transcription start sites (TSS). The chromatin in TSS regions can be re-modeled in response to abiotic stress, indicating conditional expression of young genes. Furthermore, transcripts of young genes in Arabidopsis tend to be targeted by nonsense-mediated RNA decay, presenting another layer of regulation limiting their expression. Together, these data suggest that transcriptional and post-transcriptional mechanisms contribute to the conditional expression of young genes, which may alleviate purging selection while providing an opportunity for phenotypic exposure and functionalization.

Disruption of c-di-GMP signaling networks unlocks cryptic expression of secondary metabolites during biofilm growth in Burkholderia pseudomallei

The regulation and production of secondary metabolites during biofilm growth of Burkholderia spp. is not well understood. To learn more about the crucial role and regulatory control of cryptic molecules produced during biofilm growth, we disrupted c-di-GMP signaling in Burkholderia pseudomallei, a soil-borne bacterial saprophyte and the etiologic agent of melioidosis. Our approach to these studies combined transcriptional profiling with genetic deletions that targeted key c-di-GMP regulatory components to characterize responses to changes in temperature. Mutational analyses and conditional expression studies of c-di-GMP genes demonstrates their contribution to phenotypes such as biofilm formation, colony morphology, motility, and expression of secondary metabolite biosynthesis when grown as a biofilm at different temperatures. RNA-seq analysis was performed at varying temperatures in a ΔII2523 mutant background that is responsive to temperature alterations resulting in hypo- and hyper- biofilm forming phenotypes. Differential regulation of genes was observed for polysaccharide biosynthesis, secretion systems, and nonribosomal peptide and polyketide synthase (NRPS/PKS) clusters in response to temperature changes. Deletion mutations of biosynthetic gene clusters (BGCs) clusters 2, 11, 14 (syrbactin), and 15 (malleipeptin) in wild-type and ΔII2523 backgrounds also reveals the contribution of these BGCs to biofilm formation and colony morphology in addition to inhibition of Bacillus subtilis and Rhizoctonia solani. Our findings suggest that II2523 impacts the regulation of genes that contribute to biofilm formation and competition. Characterization of cryptic BGCs under differing environmental conditions will allow for a better understanding of the role of secondary metabolites in the context of biofilm formation and microbe-microbe interactions.

Chronic AMPK inactivation slows SHH medulloblastoma progression by inhibiting mTORC1 signaling and depleting tumor stem cell populations

We show that inactivating AMPK in vivo in a genetic model of medulloblastoma depletes tumor stem cell populations and slows tumor progression. Medulloblastoma, the most common malignant pediatric brain tumor, grows as heterogenous communities comprising diverse types of tumor and stromal cells. We have previously shown that different types of cells in medulloblastomas show different sensitivities to specific targeted therapies. To determine if specific populations depend on AMPK, we analyzed mice with AMPK-inactivated medulloblastomas. We engineered mice with brain-wide, conditional deletion of the AMPK catalytic subunits Prkaa1 and Prkaa2 and conditional expression SmoM2, an oncogenic Smo allele that hyperactivates Sonic Hedgehog (SHH) signaling. We compared the medulloblastomas that formed in these mice to tumors that form in AMPK-intact mice with conditional SmoM2 expression. AMPK-inactivated tumors progressed more slowly, allowing longer event-free survival. AMPK inactivation altered the cellular heterogeneity, determined by scRNA-seq, increasing differentiation, decreasing tumor stem cell populations and reducing glio-neuronal multipotency. Mechanistically, AMPK inactivation altered glycolytic gene expression and decreased mTORC1 pathway activation. Hk2-deletion reproduced key aspects of the AMPK-inactivation phenotype, implicating altered glycolysis in the tumor suppressive effect of AMPK inactivation. Our results show that AMPK inactivation impairs tumor growth through mechanisms that disproportionately affect tumor stem cell populations. As stem cells are intrinsically resistant to current cytotoxic therapy that drives recurrence, finding ways to target these populations may prevent treatment failure. Our data suggest that targeted AMPK inactivation may produce therapeutic effects in tumor stem cell populations refractory to other therapeutic approaches.

Genome-Scale Reconstruction of Microbial Dynamic Phenotype: Successes and Challenges

This review is a part of the SI ‘Genome-Scale Modeling of Microorganisms in the Real World’. The goal of GEM is the accurate prediction of the phenotype from its respective genotype under specified environmental conditions. This review focuses on the dynamic phenotype; prediction of the real-life behaviors of microorganisms, such as cell proliferation, dormancy, and mortality; balanced and unbalanced growth; steady-state and transient processes; primary and secondary metabolism; stress responses; etc. Constraint-based metabolic reconstructions were successfully started two decades ago as FBA, followed by more advanced models, but this review starts from the earlier nongenomic predecessors to show that some GEMs inherited the outdated biokinetic frameworks compromising their performances. The most essential deficiencies are: (i) an inadequate account of environmental conditions, such as various degrees of nutrients limitation and other factors shaping phenotypes; (ii) a failure to simulate the adaptive changes of MMCC (MacroMolecular Cell Composition) in response to the fluctuating environment; (iii) the misinterpretation of the SGR (Specific Growth Rate) as either a fixed constant parameter of the model or independent factor affecting the conditional expression of macromolecules; (iv) neglecting stress resistance as an important objective function; and (v) inefficient experimental verification of GEM against simple growth (constant MMCC and SGR) data. Finally, we propose several ways to improve GEMs, such as replacing the outdated Monod equation with the SCM (Synthetic Chemostat Model) that establishes the quantitative relationships between primary and secondary metabolism, growth rate and stress resistance, process kinetics, and cell composition.

USB1 Is a miRNA Deadenylase That Regulates Hematopoietic Development

Poikiloderma with neutropenia (PN)is an autosomal-recessive bone marrow failure (BMF) syndrome in which patients harbor homozygous or compound heterozygous mutations in the human gene C16orf57, which encodes the evolutionarily conserved RNA 3' to 5' exonuclease U6 biogenesis 1 (USB1). USB1 is required for the proper maturation of U6 and U6atac snRNAs, core components of the spliceosome, and consequently, splicing defects have been observed in yeast and zebrafish models with USB1 deficiency. However, lymphoblastoid cells from PN patients do not exhibit reduced U6 snRNA levels and have normal pre-mRNA splicing, establishing PN as a singular BMF syndrome, where the underlying genetic cause has been identified but the molecular mechanisms leading to tissue failure remain obscure. To investigate the role of USB1 in a physiological context, we utilized CRISPR/Cas9 to create human embryonic stem cells (hESCs) containing a frequently occurring c.531_del_A loss-of-function mutation in the USB1 gene (USB1_c.531_del_A hESCs). USB1_c.531_del_A hESCs have normal karyotype, normal growth rate, and retain pluripotency, indicating that clinically-relevant mutations in USB1 are not deleterious in undifferentiated hESCs. To elucidate the role of USB1 during hematopoiesis, we performed serum-free hematopoietic differentiations to derive hematopoietic progenitor cells from WT and USB1_c.531_del_A hESCs. The formation of definitive hematopoietic progenitors (CD45+) was decreased in USB1 mutant cells compared to WT cells, and definitive colony potential analysis showed compromised colony formation in USB1 mutants. These observations indicate that loss-of-function mutations in USB1 negatively influence hematopoiesis. Additionally, as PN is associated with severe non-cyclic neutropenia, we analyzed the potential of neutrophil formation in WT and USB1 mutant cells. USB1 mutants have reduced formation of CD15+/CD66b+ lineages, indicating abnormal neutrophil development. Conditional expression of WT USB1 in USB1_c.531_del_A mutant cells rescued these phenotypes, leading to normal hematopoietic development. Interestingly, USB1 mutants showed no reduction in the overall levels of U6 and U6atac snRNAs, similar to what was observed in patient cells. To identify other possible targets of USB1, we sequenced the transcriptome and miRome of WT and USB1 mutant cells in different stages of hematopoietic development. Through these analyses, we demonstrate that hematopoietic failure in USB1 mutants is caused by dysregulated miRNA levels during blood development, due to a failure to remove destabilizing 3' end oligo(A) tails added by PAPD5/7. Moreover, we demonstrate that modulation of oligoadenylation through genetic or chemical inhibition of PAPD5/7 rescues the defective hematopoiesis observed in USB1 mutants. This work indicates USB1 acts as a miRNA deadenylase and suggests PAPD5/7 inhibition as a potential therapy for PN. Disclosures Parker: Faze Therapeutics: Other: Co-founder.

Impaired RAS Proteolysis Drives Clonal Hematopoietic Transformation

Recently, the protein LZTR1 (leucine zipper-like transcriptional regulator 1) was discovered as an adaptor for a cullin 3 complex responsible for ubiquitin-mediated degradation of RAS proteins. While these data provided a novel mechanism for RAS protein regulation, there is considerable controversy as to which RAS paralogs are physiologic substrates of LZTR1. In parallel, dysregulated LZTR1 expression via aberrant splicing and mutations in both LZTR1 as well as the RAS GTPase and LZTR1 substrate RIT1 were identified in patients with clonal hematopoietic disorders. However, the effects of these alterations on normal and maliganant hematopoiesis have not been evaluated. Here we utilized a series of genetically engineered murine models for germline and conditional deletion of LZTR1, RIT1, and expression of oncogenic RIT1 mutant which revealed a key role for LZTR1 in the regulation of hematopoietic stem cell (HSC) self-renewal and delineated a series of LZTR1-regulated substrates in hematopoietic cells. Consistent with a role for LZTR1 alterations in the Noonan Syndrome, germline homozygous deletion of Lztr1 was associated with lethality between embryonic day 17.5 and birth. Lztr1-/- fetuses had massive dyserythropoiesis and apoptosis of fetal liver hematopoietic cells. Competitive transplantation of E14.5 Lztr1 null fetal liver or bone marrow from 6-week-old Mx1-cre Lztr1 conditional knockout (cKO) mice resulted in striking increased self-renewal in primary and secondary competitive transplantation assays in vivo (Fig.A-B). Interestingly, recipient animals reconstituted with Lztr1-/- cells developed fatal myeloid and lymphoid leukemias characterized by anemia, thrombocytopenia, and increased myeloid and B-lymphoid cells (Fig.C-D). In order to identify the LZTR1 substrates responsible for effects on HSCs, we evaluated levels of all RAS GTPases in Lztr1 null HSCs. This revealed elevated KRas, NRas, MRas, and Rit1 protein in LZTR1 KO cells (Fig.E), with RIT1 being most prominently elevated. Evaluation of a cohort of 4,113 patients with hematologic malignancies identified 41 patients with somatic RIT1 mutations, the majority of which cluster in the switch II region and escape LZTR1-mediated ubiquitination, resulting in RIT1 protein accumulation (Fig.F-H). Given that the impact of RIT1 mutations on hematopoiesis is unknown, we next compared Lztr1 cKO with conditional expression of one of the most common leukemia-associated RIT1 mutants that escapes LZTR1-mediated ubiquitin (Rit1 M90I). Both Lztr1 cKO and Rit1 M90I conditional expression conferred GM-CSF hypersensitivity to HSCs in vitro, cytokine independent growth to human AML cell lines in vitro, and strong competitive self-renewal in vivo (Fig. I-J). Consistent with RIT1 mutations being found primarily in myeloid neoplasm patients, aged Mx1-cre Rit1M90I/WT mice developed fatal MPN, MDS, and mixed MDS/MPN disorders (Fig.K), which were serially transplantable into sublethally irradiated recipients. Despite convergent effects of LZTR1 and RIT1 on clonal HSC advantage, LZTR1 null cell lines did not solely require RIT1 for HSC advantage as revealed by Lztr1/Rit1 double KO mice. We therefore next carried out a series of experiments in RAS-less cells and whole genome CRISPR screens to delineate factors required for LZTR1 mediated hematopoietic transformation. This revealed that KRAS as well as MRAS and its RAF phosphatase partner SHOC2 were selective dependencies for LZTR1-mediated transformation. These data indicate that multiple RAS GTPases as well as RAF activation are required for LZTR1-mediated transformation (Fig.L). While considerable prior research has evaluated oncogenic alleles of RAS which alter RAS-GTP hydrolysis on hematopoiesis, the role of modulating RAS protein abundance on hematopoiesis is unknown. Here we identify RAS proteolysis as a novel regulator of HSC function, define the spectrum of RIT1 mutations in leukemia, and identify LZTR1 and RIT1 mutations as drivers of leukemogenesis. The discovery of RAS proteolysis as a novel driver of leukemogenesis has important therapeutic implications given efforts to therapeutically degrade RAS family members. Finally, the clinical importance of K/NRAS mutations on resistance to therapies in AML motivates future studies on the potential clinical impact of LZTR1 and RIT1 alterations in myeloid neoplasm patients. Figure 1 Figure 1. Disclosures Abdel-Wahab: H3B Biomedicine: Consultancy, Research Funding; Merck: Consultancy; Foundation Medicine Inc: Consultancy; Prelude Therapeutics: Consultancy; LOXO Oncology: Consultancy, Research Funding; Lilly: Consultancy; AIChemy: Current holder of stock options in a privately-held company, Membership on an entity's Board of Directors or advisory committees; Envisagenics Inc.: Current holder of stock options in a privately-held company, Membership on an entity's Board of Directors or advisory committees.

Genetic analysis of Hsp90 function in Cryptococcus neoformans highlights key roles in stress tolerance and virulence

The opportunistic human fungal pathogen Cryptococcus neoformans has tremendous impact on global health, causing 181,000 deaths annually. Current treatment options are limited, and the frequent development of drug resistance exacerbates the challenge of managing invasive cryptococcal infections. In diverse fungal pathogens, the essential molecular chaperone Hsp90 governs fungal survival, drug resistance, and virulence. Therefore, targeting this chaperone has emerged as a promising approach to combat fungal infections. However, the role of Hsp90 in supporting C. neoformans pathogenesis remains largely elusive due to a lack of genetic characterization. To help dissect the functions of Hsp90 in C. neoformans, we generated a conditional expression strain in which HSP90 is under control of the copper-repressible promoter CTR4-2. Addition of copper to culture medium depleted Hsp90 transcript and protein levels in this strain, resulting in compromised fungal growth at host temperature; increased sensitivity to stressors, including the azole class of antifungals; altered C. neoformans morphology; and impaired melanin production. Finally, leveraging the fact that copper concentrations vary widely in different mouse tissues, we demonstrated attenuated virulence for the CTR4-2p-HSP90 mutant specifically in an inhalation model of Cryptococcus infection. During invasion and establishment of infection in this mouse model, the pathogen is exposed to the relatively high copper concentrations found in the lung as compared to blood. Overall, this work generates a tractable genetic system to study the role of Hsp90 in supporting the pathogenicity of C. neoformans and provides proof-of-principle that targeting Hsp90 holds great promise as a strategy to control cryptococcal infection. Article Summary Hsp90 is a conserved molecular chaperone that modulates virulence traits and drug resistance in fungal pathogens. Despite the potential of Hsp90 as a target for antifungal development, genetic characterization remains lacking in Cryptococcus neoformans. Here, we report generation of a C. neoformans HSP90 conditional expression strain. Utilizing this genetic tool, we found depletion of Hsp90 impacted tolerance to environmental stresses, growth at physiological temperature, and virulence in vivo. Thus, we suggest targeting Hsp90 is a viable strategy for treating cryptococcosis.