Figures
Abstract
Telomeres are specialized nucleoprotein structures situated at eukaryotic chromosome ends, vital for preserving genetic information during cell replication. Telomerase, a holoenzyme composed of telomerase reverse transcriptase and an RNA template component, is responsible for elongating telomeric DNA. The intracellular trafficking of the telomerase RNA (TER) varies, either staying in the nucleus or exiting to the cytoplasm, depending on the organism. For example, in Saccharomyces cerevisiae, the RNA template is exported to the cytoplasm, whereas in mammalian cells and protozoa, it remains within the nucleus. Aspergillus nidulans, a filamentous fungus, offers an outstanding model for investigating telomeres and telomerase due to its characterized telomerase components, exceptionally short and tightly regulated telomeres, and innovative heterokaryon rescue technique. To determine the pathway of telomerase RNA trafficking in A. nidulans, we leveraged its unique capabilities to exist in both uni- and multi-nucleate states within a heterokaryon. This involved creating a TER knockout A. nidulans strain (TERΔ) and examining the resulting colonies for signs of heterokaryon formation. Heterokaryons would imply the export of TER from one nucleus and its import into a TERΔ nucleus. Interestingly, the TERΔ strain consistently failed to produce heterokaryons, instead giving rise to likely diploid colonies. This surprising finding strongly implies that telomerase assembly predominantly takes place within the nucleus of A. nidulans, distinguishing it from the biogenesis and trafficking pattern observed in yeast.
Citation: Day JK, Palmero BJ, Allred AL, Li J, Hooda FB, Witte G, et al. (2025) Trafficking of the telomerase RNA using a novel genetic approach. PLoS ONE 20(4): e0313178. https://doi.org/10.1371/journal.pone.0313178
Editor: Arthur J. Lustig, Tulane University Health Sciences Center, UNITED STATES OF AMERICA
Received: October 19, 2024; Accepted: February 9, 2025; Published: April 2, 2025
Copyright: © 2025 Day et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the manuscript and its Supporting Information files.
Funding: This research was funded in part by Lake Forest College Summer Research Awards for consumables. The equipment and instrumentation used in this study were originally supported by National Science Foundation Award MCB-0950957 to Karen E. Kirk. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Telomeres in the filamentous fungus Aspergillus nidulans and various other organisms consist of repetitive nucleotide sequences, specifically 5’- TTAGGG -3’ [1,2]. These sequences act as protective shields for the termini of chromosomal DNA, guarding against damage and addressing the “end replication problem” [3]. The enzyme telomerase becomes indispensable in preserving telomere length throughout DNA replication processes. Notably, A. nidulans exhibits unusually short and tightly regulated telomeres, typically containing roughly 110 bp in the studied cell types, compared to the multiple kilobase long telomeres of other organisms [1,2,4].
Telomerase is minimally made of two essential components: the telomerase reverse transcriptase and the telomerase RNA which serves as the template for the synthesis of the G-rich telomeric DNA [5]. In Aspergillus nidulans, genes encoding both the telomerase reverse transcriptase, trtA [4], and the telomerase RNA, TER [6,7], have been identified, yet the biogenesis and trafficking of the components has not been well-characterized. While previous evidence relied on homology to suggest the involvement of telomerase RNA (TER) in telomerase activity, we now aim to delete the TER gene to investigate a functional role. Specifically, it remains uncertain whether TER stays within the nucleus for assembly with trtA or first leaves the nucleus.
In mammalian cells, when the protein component of telomerase (hTERT) was knocked down, the RNA template (hTR) was observed only in the nucleus [8]. Since hTR was not observed in the cytoplasm, it is believed to remain in the nucleus. Similarly, the TERs in Leishmania, Trypanosoma, and ciliated protozoa appear in the nucleus, not in the cytoplasm [9–11]. In contrast, yeast follows a distinctly different mechanism. In Saccharomyces cerevisiae, TER (TLC1) is exported from the nucleus through the nuclear export pathway [12,13]. TERT (Est2p) then associates with TLC1 to enter the nucleus. The biogenesis and trafficking of A. nidulans TER could align with the yeast-like pathway, exiting the nucleus, or potentially follow the mammalian approach, where TER remains within the nucleus.
To investigate whether A. nidulans TER assembles with trtA in the nucleus or the cytoplasm, we harnessed the unique A. nidulans life cycle. During the hyphal stage, A. nidulans is characterized by its multinucleate state [14], which can be manipulated to generate heterokaryons. These heterokaryons house two or more genetically distinct nuclei within the same cytoplasm [15,16]. A. nidulans also produce uninucleate conidia from the heterokaryotic hyphae, each conidium containing one or the other genetically distinct nucleus. This setup allows us to employ the heterokaryon rescue technique, a method for determining the essential nature of a specific gene [15]. This rescue technique has been extremely useful for the vast majority of essential A. nidulans genes examined, such as tubulins, nucleoporins, cell cycle and cyclin genes, genes involved in sexual development, and dozens of others [17–20].
Our prior studies have established the essential role of trtA in A. nidulans [4]. Notably, we observed that germinated conidia from a heterokaryon— having nuclei deficient in trtA (trtAΔ) and those containing the functional trtA (trtA+)— exhibit significantly shorter telomeres compared to a wild-type trtA + haploid strain. This underscores the necessity of trtA in precise telomere length regulation. Given that most organisms, with the exception of some plants [21], possess a single essential telomerase RNA gene, and considering the absence of evidence for a second TER gene in A. nidulans [6], the heterokaryon rescue technique remains a viable and insightful approach to studying TER trafficking.
This is the first study of telomerase RNA trafficking in a filamentous fungus using the heterokaryon technique. In this investigation, we utilized a genetic knockout approach to target the telomerase RNA gene TER, subsequently monitoring whether heterokaryons formed. The emergence of heterokaryons would imply the export of TER mRNA from the nucleus, facilitating rescue of telomerase activity between wild-type TER and TERΔ nuclei within the heterokaryon. Surprisingly, our findings did not reveal any instances of heterokaryon formation following TER gene deletion, strongly suggesting that TER RNA does not undergo nuclear export in A. nidulans. Furthermore, our results revealed that TERΔ cells rescued themselves through nuclear fusion, establishing likely diploid nuclei, thus ensuring the presence of all requisite genetic components for survival within a single nucleus. Our observations suggest that telomerase biosynthesis appears to stay within the nuclei of A. nidulans, aligning with the patterns observed in vertebrate cells and distinguishing it from yeast.
Results
Formation of heterokaryons depends on TER export
The formation of heterokaryons is contingent upon the export of telomerase RNA (TER). In our investigation into the potential nuclear export of TER, we employed heterokaryon rescue [15]. This technique enables the propagation of hyphal cells containing multiple nuclei, allowing the rescue of a nucleus with a deleted essential gene by another nucleus within the same cytoplasm where the gene remains intact. We targeted the telomerase RNA gene (TER) and separately used the telomerase reverse transcriptase gene (trtA) as a control. Through the generation of a linear DNA deletion construct containing the pyrGAf gene flanked by targeting sequences adjacent to TER, we facilitated the replacement of TER with pyrGAf via transformation and homologous recombination (TERΔ::pyrGAf). The pyrGAf is an essential gene in uracil and uridine production and the A. nidulans strain used in this study, SO451 (FGSC A1166), has a pyrG89 mutation, rendering it unable to produce uracil and uridine (UU).
As a control, we created trtA heterokaryons following established procedures [4]. The nuclear export of trtA mRNA is critical for translation into the trtA protein. Consequently, the presence of trtA mRNA and protein in the cytoplasm allows for mutual rescue between trtAΔ::pyrGAf and trtA + ::pyrG- nuclei. The trtA protein, capable of entering all nuclei in the heterokaryon, ensures the presence of a functional telomerase enzyme, serving as an ideal control for these experiments.
In the context of TER + ; pyrG89 and TERΔ::pyrGAf; pyrG89 nuclei coexisting in a heterokaryon (Fig 1A), successful cross-complementation and heterokaryon growth on pyrGAf selective media hinge on the export of components from the nucleus (Fig 1B , 1C). Thus, if the TER + ; pyrG89 nucleus exports TER, it can combine with the translated trtA protein in the cytoplasm. This complex can then move into a TERΔ::pyrGAf; pyrG89 nucleus, rescuing it with an active telomerase enzyme (Fig 1B). Rescue of TERΔ::pyrGAf; pyrG89 will result in proper production of uracil and uridine, keeping the hyphal cell alive. In contrast, if TER remains in the nucleus, the TERΔ::pyrGAf; pyrG89 nucleus cannot synthesize a functional telomerase enzyme, precluding its rescue in a heterokaryon (Fig 1C). This functional assay addresses the question of TER export from the nucleus by observing heterokaryon formation post TER deletion.
A. The asexual life cycle of Aspergillus nidulans includes uni- and multi-nucleate stages. B and C. Diagrams represent heterokaryotic cells on selective media lacking UU. B. 1) If TER (blue) is exported from the TER + nucleus, 2) it can join with trtA (green) in the cytoplasm. 3) Functional telomerase enters both TER + and TERΔ::pyrGAf; pyrG89 nuclei to maintain telomeres. 4) The TERΔ::pyrGAf; pyrG89 nucleus transcribes orotidine-5’-phosphate decarboxylase (pyrG), producing uracil and uridine (purple) for the cell. The cell survives through this heterokaryotic relationship. C. 1) If TER is not exported from the TER + nucleus, 2) trtA in the cytoplasm remains incomplete and 3) can only function in the TER + nucleus. The TERΔ nucleus cannot replenish its telomeres, and ultimately the cell will die, 4) even if it produces uridine and uracil.
No TERΔ transformants formed heterokaryons
To delete TER, we engineered a knockout construct designed to concurrently eliminate TER and introduce the functional pyrGAf sequence into the TER locus as a selectable marker (Fig 2). A parallel knockout construct for trtA (following a similar protocol in [4]) served as the control. We transformed our TER and trtA knockout constructs into the A. nidulans strain SO451 and obtained 20 TERΔ and 29 trtAΔ colonies growing on selective media lacking uridine and uracil, indicating the integration of the functional pyrGAf knock-in. To subsequently determine if the transformed cells were heterokaryons, all 20 TERΔ and 18 of the trtAΔ transformants were analyzed by phenotypic tests and PCR analyses.
A. Schematic of the TER knockout construct generation and subsequent gene replacement. The TER locus (red) is replaced with the Aspergillus fumigatus pyrG gene (pyrGAf, gray) through fusion PCR. This pyrGAf gene synthesizes uridine and uracil, compensating for the pyrG89 mutation in the parent SO451 A. nidulans strain. B. PCR amplification of the construct fragments. Lane 2 shows the pyrGAf-containing fragment (~1700 bp, gray), while lanes 4 and 5 display the left (~1000 bp, blue) and right (~1000 bp, purple) flanking regions, all amplified to the expected sizes. No template DNA (-) in the PCR reaction. C. The TER knockout construct formation. Lane 2 shows the complete TER knockout construct, ~ 3500 bp. Faint bands between 2,000 and 3,000 bp indicate unligated fragments.
Uninucleate conidia from transformant colonies were subjected to a heterokaryon test to determine the viability of TERΔ::pyrGAf; pyrG89 nuclei and their dependence on TER + ; pyrG89 nuclei in a heterokaryotic state. The heterokaryon test is an assay conducted through conidiation of the transformant (Fig 3). The test involves streaking conidia on both nonselective media containing UU and selective media lacking UU. Since conidia are uninucleate, they cannot complement each other as multinucleate hyphal cells can. The predicted outcomes illustrate that on nonselective media, TER + ; pyrG89 conidia from transformant colonies (assumed to be heterokaryons) will grow well due to the presence of UU. TERΔ::pyrGAf; pyrG89 conidia, lacking functional TER, are expected to die due to compromised telomere maintenance [22,23], and thus will not be visible as the TER + ; pyrG89 cells overgrow them. On selective media lacking UU, TER + ; pyrG89 conidia will not grow, while TERΔ::pyrGAf; pyrG89 conidia may initially grow but fail to sustain growth without TER. Consequently, we expect minimal to no growth on selective media for colonies potentially undergoing heterokaryon rescue, harboring genetically distinct nuclei.
Conidia from transformants are plated on A. nonselective media containing UU and B. selective media lacking UU. Bubbles in each sector represent expected growth for conidia of each genotype shown in the legend, with circles representing conidia and white lines indicating growth. 1) Heterokaryon with Essential Gene Knockout: Nonselective Media (A): Healthy growth due to the presence of the essential gene and UU supplementation. Selective Media (B): Weak, sickly brown growth, as pyrGAf conidia cannot maintain telomeres without UU. No growth of conidia containing the essential gene due to lack of UU. 2) Nonessential Gene Knockout: Nonselective Media (A) and Selective Media (B): Healthy growth of pyrGAf conidia, indicating the gene of interest is nonessential. 3) Diploid Formation with Essential Gene: Nonselective Media (A) and Selective Media (B): Healthy growth on both media types, as diploid conidia can grow regardless of UU presence. 4) Heterologous Recombination: Nonselective Media (A) and Selective Media (B): Healthy growth, as conidia contain nuclei with both genes due to pyrGAf integration elsewhere in the genome, somewhere outside of the target gene locus. This haploid conidium grows well on both media types because it contains wild-type copies of both essential genes.
A sample of the experimental results from the heterokaryon test are shown in Fig 4. The trtAΔ control successfully yielded heterokaryons. After trtAΔ deletion, 21 of the 29 transformant colonies produced conidia with robust growth on nonselective media and limited growth on selective media, aligning with predictions in quadrant 1 of Fig 3. Limited growth on selective media was characterized by filling no more than a fifth of the streaked portion and appearing brown rather than white. Several trtAΔ conidia on selective media displayed sectoring, indicative of hyphae attempting to grow without maintaining an appropriate balance of trtAΔ::pyrGAf; pyrG89 and trtA + ::pyrG89 nuclei. From the trtAΔ transformants investigated, 12/18 were heterokaryons (Table 1).
The heterokaryon tests demonstrate distinct growth patterns between TERΔ and trtAΔ primary transformant colonies, indicating heterokaryon formation in trtAΔ but not in TERΔ. Healthy growth is observed on the nonselective (+UU) plates for both TERΔ (sectors 1 and 2) and trtAΔ (sectors 3 and 4) samples. On the selective (-UU) plate, TERΔ colonies exhibit healthy growth, while trtAΔ colonies show severely impaired growth. This lack of growth in the trtAΔ background indicates the formation of a trtAΔ heterokaryon, but TERΔ colonies did not form heterokaryons.
Surprisingly, in the TERΔ heterokaryon tests, all conidia from the 20 transformant colonies exhibited robust growth on both selective and nonselective media, as illustrated in Fig 4. Such healthy growth on selective media was not anticipated in the heterokaryon test, indicating that 0/20 transformants were heterokaryons (Table 1). This suggested that these transformants arose instead by nonessential gene knockout, diploid formation, or heterologous recombination, as depicted in sections 2-4 of Fig 3. Since none of the TERΔ transformant colonies displayed heterokaryon phenotypes, it was possible that TER remained intact due to heterologous recombination of the deletion construct at another genomic location. Alternatively, the cells may resort to an alternative survival mechanism— the formation of a diploid cell. Fusion of genetically distinct nuclei, such as TER + ; pyrG89 and TERΔ::pyrGAf; pyrG89, result in a diploid cell (TER + /TERΔ::pyrGAf; pyrG89/pyrG89) capable of producing TER and surviving without added UU. These heterozygous diploid colonies yield conidial spores adept at surviving on both selective and nonselective media.
TERΔ transformants form diploids, rather than heterokaryons
To investigate the possibility that these were diploids in the heterokaryon test results, rather than the result of a heterologous event (which happens in ~ 10% of such transformants [35]), we conducted an integration check PCR on hyphal DNA. This involved a common primer (in green), targeting the upstream region of the left flanking region (in blue) of the TER locus, along with two gene-specific primers—one within the TER + (in red, predicted to yield ~ 1600 bp) and the other within the knockout, pyrGAf (in gray, predicted to yield ~ 2300 bp) (see Fig 5A).
A. Schematic of PCR design for TERΔ transformants. The upper arrow represents the wild-type TER + amplicon (~1,600 bp), while the lower arrow corresponds to the TERΔ::pyrGAf amplicon (~2,300 bp). B. Gel electrophoresis of representative PCR products. Lane 1: Quick-Load Purple 1 kb Plus DNA Ladder. Lanes 2 and 3: The same TERΔ transformant having different amplicons in Lane 2 TER + (~1,600 bp) and Lane 3 TERΔ::pyrGAf (~2,300 bp). Lanes 4 and 5: trtA (~1,900 bp) and trtA::pyrGAf (~2,900 bp) amplicons from the trtAΔ heterokaryon. Lanes 6 and 7: Same amplicons as lanes 4 and 5 but from trtAΔ diploids. Lanes 8 to 13: Parent SO451 controls using trtAΔ and TERΔ primers on SO451 control DNA, with the pyrGAf amplicon absent as it has not been knocked in. Lane 12: Protection of Telomeres (POT1) gene as a PCR positive control. Lane 13: Negative no template control.
We investigated the genotypes of the TERΔ transformants. An integration check PCR, executed on DNA extracted from conidia following the TERΔ deletion, validated that 15 out of the 20 transformants were heterozygous diploids. These diploids harbored both TERΔ::pyrGAf; pyrG89 and TER + ; pyrG89 genotypes. Fig 5B illustrates a representative PCR result, with Lanes 2 and 3 showing amplification from the same TERΔ transformant. Lane 2 shows the ~ 1600 bp fragment from the TER + amplicon, and Lane 3 shows the ~ 2300 bp fragment from the TERΔ::pyrGAf amplicon. It is important to note that successful amplification in both PCRs could indicate either a genuine heterokaryon or a heterozygous diploid, but given the phenotypic outcome from the heterokaryon test (Fig 4), these transformants are likely diploid. The five remaining transformants did not match our parameters for correct integration due to fragment size and TER knockout, possibly indicating non-targeted heterologous integration, and we did not investigate further these transformants.
For the trtAΔ control, integration check PCR was performed on 12 of the transformants that exhibited heterokaryon growth patterns and 6 of the transformants that exhibited potential diploid growth patterns (representative PCR in Fig 5B and Table 1). DNA analyses were not performed on all trtAΔ colonies because some did not survive, as heterokaryons can be unstable. DNA for the PCRs was isolated from the hyphae of the trtAΔ transformants because heterokaryon hyphae should contain nuclei with the trtAΔ::pyrGAf; pyrG89 and trtA + ; pyrG89 genotypes.
Diploid colonies exhibit enlarged nuclei
To further substantiate the diploid formation observed in the TERΔ strains, prompted by the outcomes of the heterokaryon tests and PCR analyses, we employed DAPI staining on the conidia. We expected that the TERΔ DAPI stain signal would exhibit a noticeable increase compared to the SO451 parent strain, providing additional evidence of heterozygous diploids.
Conidia from three selected TERΔ transformant colonies, subjected to DAPI staining, demonstrated markedly elevated DAPI signals compared to the SO451 conidia (see Fig 6A). Statistical analysis revealed that the TERΔ conidia exhibited significantly higher DAPI stain intensity, t(4) = 5.18, p = 0.00659, and stain volume (µm3), t(4) = 6.42, p = 0.00302 (see Fig 6B , 6C). The volume of the TERΔ DAPI stains (mean = 2.84, standard deviation = 0.35) was approximately double that of the SO451 nuclei (mean = 1.44, standard deviation = 0.15). Similarly, the intensities of the TERΔ DAPI stains (mean = 118.21, standard deviation = 10.05) were roughly 1.5 times that of the SO451 stains (mean = 79.98, standard deviation = 7.89). These findings strongly indicate that the TERΔ transformants are diploids, revealing a substantial increase in DNA content per nucleus, complementing the evidence from the heterokaryon test and integration check DNA analysis.
A. Representative DAPI-stained conidia from a TERΔ diploid transformant colony and a parent haploid SO451 colony. The DAPI (left) and merge (right) images are shown for each conidium. B and C. Bar graphs depicting the (B) mean intensity and (C) mean volume (nucleus size) for TERΔ (shades of blue) and the haploid SO451 strain (red/orange) with standard error bars. Results show that TERΔ transformants have nuclei nearly double the size of the SO451 DAPI-stained nuclei. The DAPI stain intensity for the TERΔ background is approximately 1.5 times that of the SO451. ( * = p < 0.05, ** = p < 0.005).
Our data strongly suggest that the TER knockout does not result in heterokaryon formation but instead leads to diploid formation. Consequently, we conclude that telomerase RNA most likely remains within the nucleus, where it assembles with trtA to form the telomerase enzyme in A. nidulans.
Discussion
In this study, we employed the heterokaryon rescue technique in a novel way to investigate the nuclear export of telomerase RNA (TER) in Aspergillus nidulans. Contrary to our expectations based on TER’s essential nature and observations from numerous other essential genes in A. nidulans, the TERΔ strain failed to form heterokaryons. This lack of heterokaryon formation suggests that TER likely remains in the nucleus and is not able to rescue the nucleus lacking TER. In contrast, trtAΔ heterokaryons formed successfully, indicating that trtA mRNA, which requires export for translation, is shared among nuclei in heterokaryons. Our findings suggest that telomerase RNA in A. nidulans follows a trafficking pathway more similar to that of vertebrate cells than yeasts.
Telomerase RNAs exhibit remarkable diversity in structure, biogenesis, and trafficking pathways across organisms. Structurally, TERs range from ~ 150 nucleotides in ciliates to over 2000 nucleotides in filamentous fungi [7,24,25]. Despite these differences in size, nearly all TERs share common ancestral core elements, including a complex tertiary pseudoknot and a three-way junction, both crucial for enzymatic activity, among others [26,27].
Yeast telomerase RNAs share several structural features with those of A. nidulans and other fungi, though with key distinctions [6,7,26,28]. For instance, the S. cerevisiae telomerase RNA, TLC1, contains an Sm7 binding site that is hypothesized to function in the cytoplasm [29,30]. The Sm7 complex may stabilize telomerase RNA during cytoplasmic shuttling [31] before it re-enters the nucleus to assemble into the active telomerase complex [32,33]. While some ascomycetes like A. nidulans and basidiomycetes such as Ustilago maydis also possess predicted Sm binding sites, their specific roles and subcellular localization require further investigation. Another significant difference between A. nidulans and yeast is the lack of Ku protein interaction with telomerase RNA. In yeast, yKu70 binds to the TLC1 sequence [34], promoting nuclear transport [8,30]. However, no binding sites for nKuA have been identified in A. nidulans or any other filamentous fungus [6]. Nevertheless, deletion of the non-essential nKuA in A. nidulans leads to a very small but consistent reduction (~10–15 bp) in telomere length [4,35], suggesting a minor role in telomere maintenance. Notably, while yeast telomerase RNAs have been shown to traffic to the cytoplasm, there is no evidence, including from this study, that telomerase RNA from any filamentous fungus undergoes cytoplasmic trafficking.
The trafficking of TER in A. nidulans, suggested by these studies, resembles that of vertebrate cells despite multiple differences in subnuclear organization. In vertebrates, the telomerase RNA (hTR) does not normally traffic outside the nucleus, except potentially in degradation [36,37]. hTR biogenesis occurs in the nucleolus and Cajal bodies [38,39], where it forms an active complex with TERT [40]. Microscopic techniques, such as FISH and live-cell imaging, have confirmed this nuclear localization [41,42]. However, even in coilin knockout cells that completely lack Cajal bodies, the hTR seems to traffic in the nucleus normally [43,44], thus raising questions about whether Cajal bodies play an essential role in hTR trafficking. Although A. nidulans lacks canonical Cajal bodies [45], it may possess analogous non-membranous structures for TER biogenesis and trafficking. Therefore, while the localization of A. nidulans TER may resemble vertebrate nuclear transport overall, the specific compartmentalization within the nucleus may differ.
The heterokaryon rescue technique is a powerful genetic approach not available in other systems, potentially offering higher sensitivity than biochemical methods or standard FISH. Our immediate future direction is to use single molecule FISH (smFISH) [29,46,47] to provide higher sensitivity and specificity. While the lack of heterokaryon formation in TERΔ strains supports nuclear localization of TER, we cannot entirely rule out the possibility that wild-type TER exits the TER+ nucleus but fails to enter the TERΔ nucleus. However, this scenario seems unlikely given that TrtA protein functions normally in this context. In addition, we cannot formally exclude the possibility that the identified TER is non-essential and that an essential, highly divergent TER variant has yet to be observed. However, the identification of survivors as likely diploids virtually eliminates this unlikely possibility. Thus, our conclusion that TER remains within the nucleus is the most likely scenario.
Although deletion of TER did not produce any heterokaryons, colonies were formed using an alternate mechanism for survival: the heterozygous diploids [48,49]. This was confirmed by growth patterns, PCR, and DAPI staining. Diploid nuclei had higher DAPI intensity and larger nuclear volumes, an infrequent but advantageous event in A. nidulans. This technique, easier than conidial or hyphal analysis, may be used in the future to assess ploidy. By forming diploids, the telomeres in the nucleus lacking TER could still be extended by the complete telomerase with the TrtA protein and TER RNA. The complete lack of heterokaryon formation and the only surviving colonies being heterozygous diploids strongly supports that the TER RNA is not being exported.
Through heterokaryon rescue, we have demonstrated that A. nidulans TER likely follows a vertebrate-like nuclear trafficking pathway, never exiting the nucleus. With its exceptionally short telomeres ~110 bp [1,4], A. nidulans depends on highly regulated TER biogenesis and trafficking. These telomeres, potentially too short to form a typical T-loop, may rely on alternative protective mechanisms [50,51]. In contrast, many model organisms, including most human tissues, exhibit less dependence on consistent telomere extension due to the greater flexibility afforded by their relatively long telomeres [52–54]. The precise regulation in A. nidulans makes it a valuable model for investigating telomerase RNA trafficking and telomere regulation, particularly in systems with minimal tolerance for telomerase dysregulation.
Materials and methods
Aspergillus nidulans
The A. nidulans parent strain was SO451 (Fungal Genetics Stock Center A1166), containing a knockout of the nkuA gene [35,55]. The telomeres of nkuA mutants are consistently 10-15 nucleotides shorter than those of the GR5 strain having wildtype nkuA [4]. The SO451 strain also carries the wA3 mutation resulting in white conidia, and the pyrG89 mutation which allows growth only on supplied uracil and uridine [15].
Generating TERΔ and trtAΔ strains
To generate heterokaryons [15], we disrupted the TER gene. This was accomplished through the use of a linear DNA-deletion construct, which facilitated the integration of the Aspergillus fumigatus pyrG (pyrGAf) gene into the TER locus. The pyrGAf gene exhibits sufficient dissimilarity from the native A. nidulans pyrG, preventing integration into the A. nidulans pyrG locus while still encoding a functional orotidine-5’-phosphate decarboxylase essential for uridine and uracil synthesis. We transformed this construct into the parent SO451 strain, and confirmed successful integration through PCR analysis, below. A similar approach was applied to the trtA gene, following the protocol for trtA in [4].
Creating the TER knockout construct
Fusion PCR was conducted using primers (Eurofins Scientific) designed to amplify three fragments: left and right homologous arms that targeted the TER locus, and the pyrGAf gene, using Phusion® High-Fidelity DNA Polymerase. The fused construct was cloned using the Zero Blunt® TOPO® PCR cloning kit and One Shot® Chemically Competent E. coli. Plasmids containing the knockout construct were extracted from E. coli using the QIAprep® Spin Miniprep Kit.
In order to obtain the knockout construct, PCR was conducted using primers that annealed a few bases nested within the construct. The isolated construct sequence was confirmed to match the expected sequence by Sanger DNA sequencing performed by the University of Chicago’s Genomics Facility.
Transformation
Conidia (5x10^8) were inoculated into 25 mL of YGUU media in a 125 mL Erlenmeyer flask and grown for 6 hours at 32°C with shaking at 200 rpm. After confirming germ tube initiation, they were transferred to a lytic solution with pectinase and beta-glucanase, grown for 3 hours at 150 rpm in a fresh flask, and vigorously pipetted to generate protoplasts. Protoplast formation was monitored visually using 100x phase contrast microscopy. Protoplasts were combined with knockout constructs (or controls) and solution 4, incubated on ice and then at room temperature. They were transferred into selective molten YAG + 1 M sucrose top agar, plated in varying volumes on YAG + 1 M sucrose plates, and incubated at 32°C for 48-72 hours.
Heterokaryon test
The heterokaryon test was performed essentially as described apart from MAG media [15]. To isolate single transformants, individual colonies were grown on selective MAG plates lacking uridine and uracil (UU). After 48-72 hours at 32°C, the colonies underwent phenotypic analysis using the heterokaryon test (in concurrence with PCR analysis of transformants, below). For this test, conidia from the surface of a distinct colony (to obtain only conidia and not cells that might have more than one type of nucleus) from selective MAG colonies were streaked onto both selective plates (lacking UU) and non-selective plates supplemented with 1.12 g/L uracil and 1.2 g/L uridine. Growth was monitored after 24 hours and incubated for a total of 48 hours at 32°C. Growth patterns on these plates were compared to determine the transformants’ phenotypes. If the growth pattern is normal on nonselective and inhibited on selective media, then the transformant is most likely a heterokaryon. If there is healthy growth on both plates, this indicates either a non-essential gene has been deleted or diploid transformants were generated.
PCR analysis of transformants
Hyphae in selective liquid YG were processed for DNA extraction. Following filtration, homogenization, and phenol-chloroform extraction, DNA was purified using the GENECLEAN® Turbo Kit. DNA extraction was also performed on uninucleate conidia in the TERΔ background. Integration of the knockout construct was verified by conducting two PCRs on one transformant colony, using locus-specific, pyrGAf, and TER primers. The presence of correctly sized amplicons in both reactions confirmed the presence of both genes in the extracted DNA. PCR conditions involved 30 cycles at 98°C for 10 seconds, 60°C for 30 seconds, and 72°C for 1 minute using REDTaq® ReadyMixTM.
DAPI staining
The nuclei of transformant colonies TERΔ 1-3 and an equal number of parent SO451 colonies were stained with DAPI (protocol adapted from [56]). Conidia were grown on selective MAG plates, collected, and processed for DAPI staining. DAPI-stained conidia were imaged using UV light and differential interference contrast on a Nikon ECLIPSE TE2000-U microscope at 100x magnification. Image analysis included measuring stain radius and intensity for 50 stained conidia in each of the six samples, totaling 150 nuclei in both SO451 and TERΔ backgrounds. DAPI stain radius was measured using Nikon NIS elements, and the DAPI stain intensity was measured using a background subtraction of the average grey area in ImageJ [57].
Acknowledgments
We acknowledge Kate Fanning for diagram designs, Petra Urgacova, Meklit Yimenu, Natalie Kamau, and Allison Akins for technical assistance and Anamitra Bhattacharyya for assistance reviewing the manuscript. We are deeply grateful to Stephen and Aysha Osmani for their technical assistance, materials, guidance, and reviewing of the manuscript.
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