Freshwater ascomycetes from southern Australia: Melanascomaceae fam. nov., Melanascoma panesporagen. et. sp. nov., and Pleurotheciumbruniussp. nov.

During a survey of freshwater fungi in temperate southern Australia, two new taxa were found, Melanascoma panespora and Pleurothecium brunius. Morphological and molecular data place Melanascoma panespora in the Diaporthomycetidae representing a new genus. Melanascoma, along with Proliferophorum and Paraproliferophorum, form a new lineage and the family Melanascomaceae is introduced. Phylogenetic analyses using ITS, 28S, and 18S nrRNA gene sequences,, along with morphological examination revealed Pleurothecium brunius to be a new species of Pleurothecium, sister to P. aquaticum. Citation: Fryar SC, Catcheside DEA (2023). Freshwater ascomycetes from southern Australia: Melanascomaceae fam. nov., Melanascoma panespora gen. et. sp. nov., and Pleurothecium brunius sp. nov. Fungal Systematics and Evolution 11: 85-93. doi: 10.3114/fuse.2023.11.07.

Delineation of the IGF-II C domain elements involved in binding and activation of the IR-A, IR-B and IGF-IR.

OBJECTIVE: Human insulin-like growth factor-I and -II (IGF-I and -II) ligands share a high degree of sequence and structural homology. Despite their similarities, IGF-I and IGF-II exhibit differential receptor binding and activation characteristics. The C domains of IGF-I and IGF-II are the primary determinants of binding specificity to the insulin-like growth factor I receptor (IGF-IR), insulin receptor exon 11- (IR-A) and exon 11+ (IR-B) isoforms. DESIGN: Three IGF-II analogues were generated in order to delineate the C domain residues that confer the differential receptor binding affinity and activation properties of the IGFs. Chimeric IGF-II analogues IGF-IICI(N) and IGF-IICI(C) contained partial IGF-I C domain substitutions (IGF-I residues underlined) GYGSSSRRSR and SRVSRRAPQT, respectively. RESULTS: The IGF-IICI(N) analogue bound the IR-A and IGF-IR with high affinity but bound the IR-B with a relatively lower affinity than IGF-II, suggesting a negative interaction between the exon-11 encoded peptide in the IR-B and the C-domain. The ability of IGF-IICI(N) to activate receptors and elicit cell viability responses was generally proportional to its relative receptor binding affinity but appeared to act as a partial agonist equivalent to IGF-I when binding and activating the IGF-IR. In contrast, IGF-IICI(C) bound IGF-IR with high affinity but elicited lower receptor activation and cell viability responses. Analogue IGF-IICI(S) contained a truncated IGF-I C domain (GSSSRRAT) and generally displayed a relatively poor ability to bind, activate and elicit viability responses via each receptor. CONCLUSIONS: Together, the IGF analogues demonstrate that both flanks of the IGF-II C domain play important roles in the greater ability of IGF-II to bind and activate IR receptors than IGF-I.

Residual recombination in Neurospora crassa spo11 deletion homozygotes occurs during meiosis.

Spo11 is considered responsible for initiation of meiotic recombination in higher organisms, but previous analysis using spo11 (RIP) mutants suggests that the his-3 region of Neurospora crassa experiences spo11-independent recombination. However, despite possessing several stop codons, it is conceivable that the mutants are not completely null. Also, since lack of spo11 interferes with chromosomal pairing and proper segregation at Meiosis I, spores can be partially diploid for a period after meiosis. Thus, it is possible that the recombination observed could be an abnormal event, occurring during the period of aneuploidy rather than during meiosis. To test the former hypothesis, we generated spo11 deletion homozygotes. Using crosses heteroallelic for his-3 mutations, we showed that His(+) progeny are generated in spo11 deletion homozygotes at a frequency at least as high as in wild type and, as in the spo11 (RIP) mutants, local crossing over is not reduced. To test the latter hypothesis, we utilised mutations in either end of a histone H1-GFP fusion gene, inserted between the recombination hotspot cog and his-3, in which GFP(+) spores arise as a result of recombination in a cross between the two GFP alleles. In a control cross homozygous for spo11 (+), the frequency at which GFP(+) spores arise is comparable to the frequency of His(+) spores and glowing nuclei first appear during prophase, prior to metaphase I, as expected for a product of meiotic recombination. Similarly in spo11 deletion homozygotes, GFP(+) spores arise at high frequency and glowing nuclei are first seen before metaphase, indicating that allelic recombination occurs during meiosis in the absence of spo11. We have therefore shown that spo11 is not essential for either his-3 allelic recombination or crossing over in the vicinity of his-3, and that spo11-independent allelic recombination is meiotic, indicating that there is a spo11-independent mechanism for initiation of recombination in Neurospora.

A crossover hotspot near his-3 in Neurospora crassa is a preferential recombination termination site.

During analysis of 148 unselected Neurospora crassa octads, an above average rate of crossing over was detected within a 360-base region near the 3' end of his-3, suggesting a hotspot for crossing over about 1.8 kb away from the recombination initiation site within cog. Homozygous deletion of the 360-base region increases exchanges in his-3 and on the far side of his-3 from cog, with the heterozygote showing an intermediate increase. We conclude that recombination events initiated at cog terminate within the 360-base sequence more often than in other sections of the cog-his-3 interval and, since some of these terminations will be resolved as crossovers, a cluster of crossovers at this location is the outcome. Removal of this termination site increases the chance that an event will reach his-3, resulting in recombination within the gene, or extend past it to yield a crossover on the other side of his-3. The deleted sequence has substantial predicted secondary structure, including a complex predicted stem-loop, suggesting that DNA secondary structure may be responsible for the termination.

High density analysis of randomly selected Neurospora octads reveals conversion associated with crossovers located between cog and his-3.

We analysed 148 octads from a Neurospora cross maximised for sequence heterology in the his-3 region and detected non-Mendelian segregation at his-3, cot-1 and lys-4 loci. This was in all cases 6:2 or 2:6, with no evidence of post-meiotic segregation (PMS) in these genes. High density snp analysis was used to place crossovers between his-3 and the centromere-distal marker ad-3, and sequencing to refine the location of crossovers between his-3 and the recombination hotspot cog. Crossovers appeared to have a non-random distribution, falling close to his-3 or more than 40 kb distal, and all those in which the location was determined were flanked by sequences showing gene conversion and/or PMS amongst the polymorphisms. This octad study confirms the validity of assumptions made during random spore analyses and suggests that recombination hotspots at cot-1 and lys-4 may, unlike the relatively cold recombination initiator at the am locus, be high frequency recombinators similar to cog.

Alleles of the hotspot cog are codominant in effect on recombination in the his-3 region of Neurospora.

There are two naturally occurring functional alleles of the recombination hotspot cog, which is located 3.5 kb from the his-3 locus of Neurospora crassa. The presence of the cog+ allele in a cross significantly increases recombination in the his-3 region compared to a cross homozygous for the cog allele. Data obtained shortly after discovery of cog+ suggested that it was fully dominant to cog. However, a dominant cog+ conflicts with observations of hotspots in Saccharomyces cerevisiae and Schizosaccharomyces pombe, in which recombination is initiated independently of homolog interactions, and suggests recombination mechanisms may differ in Neurospora and yeast. We present evidence that cog alleles are codominant in effect on both allelic recombination in his-3 and crossing over between loci flanking his-3. In addition, we show that genetic background variation has at least a twofold effect on allelic recombination. We speculate that variation in genetic background, together with the complexities of recombination in crosses bearing close mutant alleles, accounts for the previous conclusion that cog+ is dominant to cog.

Guest, a transposable element belonging to the Tc1/mariner superfamily is an ancient invader of Neurospora genomes.

Guest is a transposable element of the Tc1/mariner superfamily with 30-40bp terminal inverted repeats and a TA dinucleotide target site duplication. Guest was originally discovered in the St. Lawrence 74A laboratory strain of the filamentous fungus Neurospora crassa. In this report, Guest iterations subcloned from a cosmid library of the Oakridge 74A strain were used to design PCR primers that permitted the detection of Guest in wild isolates of N. crassa. Guest is present in N. crassa as multiple copies ranging between 100bp and 2.4kb and is present in the mating type locus of several Neurospora species. Bioinformatic analysis of the entire N. crassa genome (Oakridge 74A strain) detected 48 Guest iterations. All iterations appeared to have been inactivated either by repeat-induced point mutation or sequence deletion, with the majority being remnants less than 400bp in length. The possible involvement of Guest in the evolution of the variable region that flanks the mating type idiomorphs in several Neurospora species is discussed.

Diversification of exogenous genes in vivo in Neurospora.

We have adapted the meiotic recombination hotspot cog of Neurospora crassa for shuffling exogenous DNA, providing a means of generating novel genes in situ from sequences introduced into chromosomes. Genes to be diversified are inserted between the his-3 locus and cog. Diversification crosses are heterozygous both for alleles of the exogenous DNA and for auxotrophic alleles of his-3. Progeny selected for ability to grow without histidine supplementation are enriched for exchange events within the exogenous DNA. Exchange events initiated by cog can propagate past DNA sequences mismatched for more than 370 bp and complete exchanges in patches of matched sequence as short as 24 bp, parameters that make the system suited for use in the directed evolution of genes for protein engineering. Here we demonstrate the system by shuffling human immunoglobulin kappa chain genes and also endoglucanase genes derived from different species of fungi.

Recombination at his-3 in Neurospora declines exponentially with distance from the initiator, cog.

By deletion of 1.8 kb of sequence between cog(L) and his-3 and replacement with sequences of different lengths, we have generated a set of Neurospora strains in which the distance between cog(L) and the site at which recombination is selected varies from 1.7 to nearly 6 kb. Each of the manipulated strains includes cog(L), a highly active recombination hotspot, and rec-2, thus allowing high-frequency recombination. In addition, each is a his-3 mutant, either K26 or K480. The frequency of His(+) recombinants in progeny of these crosses is inversely proportional to the distance between his-3 and cog. Specifically, there is a linear relationship between log(10) (recombination frequency) and the distance in base pairs, indicating that as distance decreases, the rate of interallelic recombination increases exponentially. An exponential relationship between distance separating markers and the chance of co-conversion has been found in both Drosophila and fission yeast, indicating that the extension of recombination events may be a stochastic process in most organisms. On the basis of these and additional data presented in this article, we conclude that recombination is initiated at cog(L) in >17% of meioses, that most conversion tracts are very short, and that few extend >14 kb.

Recombination events in Neurospora crassa may cross a translocation breakpoint by a template-switching mechanism.

To assist investigation of the effect of sequence heterology on recombination in Neurospora crassa, we inserted the Herpes simplex thymidine kinase gene (TK) as an unselected marker on linkage group I, giving a gene order of Cen-his-3-TK-cog-lpl. We show here that in crosses heterozygous for TK, conversion of a his-3 allele on one homolog is accompanied by transfer of the heterologous sequence between cog and his-3 from the other homolog, indicating that recombination is initiated centromere-distal of TK. We have identified a 10-nucleotide motif in the cog region that, although unlikely to be sufficient for hotspot activity, is required for high-frequency recombination and, because conversion of silent sequence markers declines on either side, may be the recombination initiation site. Additionally, we have mapped conversion tracts in His(+) progeny of a translocation heterozygote, in which the translocation breakpoint separates cog from the 5' end of his-3. We present molecular evidence of recombination on both sides of the breakpoint. Because recombination is initiated close to cog and the event must therefore cross the translocation breakpoint, we suggest that template switching occurs in some recombination events, with repair synthesis alternating between use of the homolog and the initiating chromatid as template.

Structure and function analysis of the calcium-related gene spray in Neurospora crassa.

The spray gene was cloned, and wildtype and mutant alleles were sequenced. Spray(+) has a 3452-bp open reading frame plus seven introns. The spray mutant had a T --> G transversion close to the carboxyl end, creating a stop codon (TGA). The sequence shows no match to genes of known function, but the carboxyl end shows seven transmembrane domains and matches putative membrane proteins of yeast. The most abundant transcript detected was 4.4 kb in size. Repeat-induced point mutagenesis produced the mutant spray phenotype. Electrophysiological analysis showed that ion fluxes in the spray plasma membrane are normal; furthermore, whereas the spray mutant was known to have no organelle-based calcium fluorescence, the cytosol shows a tip-high calcium gradient. The spray mutant is sensitive to calcineurin inhibitors. The results suggest that the SPRAY protein is located in an organellar membrane, regulating the distribution of Ca(2+) via calcineurin.

Methylation of the foreign transposon Restless in vegetative mycelia of Neurospora crassa.

Methylation of foreign and/or repeated sequences in the filamentous fungus Neurospora crassa is believed to be directed against invading transposable elements. To test this hypothesis, the fate of a transposon in N. crassa was investigated. Vectors were constructed which carried the transposon Restless, an active class-II element isolated from the fungus Tolypocladium inflatum. These vectors were introduced into N. crassa strains by protoplast transformation. Two strategies were employed: (1) ectopic multi-copy integration, and (2) site-specific single-copy integration at the his-3 locus. All ectopic transformants exhibited strong methylation as confirmed by Southern hybridization of genomic DNA digested with the methylation-sensitive endonuclease Sau3AI and the methylation-insensitive endonuclease NdeII. Single copies of Restless integrated at the his-3 locus were not methylated. These results are discussed with respect to non-RIP methylation and potential consequences for gene-tagging strategies based on the use of Restless.

Recombinational landscape across a 650-kb contig on the right arm of linkage group V in Neurospora crassa.

We have established a 650-kb walk spanning the sp to ure-1 interval on Neurospora crassa linkage group V. Loci covered by the walk are, from proximal to distal, sp; rec-2; ure-2; DNA polymerase delta; am; gul-1; ace-5; and ure-1. We have found extensive DNA polymorphism in this region and used this to examine the recombinational landscape. Crossovers are not evenly distributed over the region covered by the contig.

Polymorphism around cog extends into adjacent structural genes.

The recombination hotspot cog overlaps a highly polymorphic 950-bp region of linkage group I in Neurospora crassa. The sequence of this region in the four strains, Lindegren 25a, Lindegren A, Emerson A and St. Lawrence 74A, each differs from the others by 1.4% or more. Comparison of the sequence of St. Lawrence 74A and Lindegren 25a each side of cog shows a high level of sequence heterology extending in both directions, including the coding sequences for his-3 and a putative gene lpl with homology to yeast lysophospholipase. The St. Lawrence 74A and Lindegren 25a sequences of his-3, centromere-proximal to cog, differ at 14 nucleotides, resulting in six amino-acid variations between the predicted protein sequences. In lpl, distal from cog, the sequences differ at 19 nucleotides leading to five amino-acid differences between the predicted proteins. Sequence heterology between St. Lawrence 74A and Lindegren 25a peaks either side of cog and then declines with distance. At the am locus on linkage group V, heterology is much less but peaks close to a weak recombination hotspot 5' of the coding sequence. Uneven distribution of polymorphism along chromosomes has been explained by a hitch-hiking hypothesis in which selection for advantageous mutations causes local fixation of unselected variation. We suggest that new mutations arising from errors in recombination also contribute to the uneven distribution of polymorphism.

Evidence for negative interference: clustering of crossovers close to the am locus in Neurospora crassa among am recombinants.

In response to a conflict between two mapping studies in the predicted orientation of the allele map with respect to the centromere, Fincham proposed that recombination events at the Neurospora am locus rarely have an associated crossover. Fincham considered that the elevated levels of crossing over between flanking markers in am recombinants resulted from negative interference, an increased probability of a nearby second event, and on this basis predicted a clustering of crossing over near am in these recombinants. In this article we reevaluate the data from three mapping studies of the am locus and report molecular evidence that shows crossovers to be clustered immediately proximal to am in am recombinants.

Analysis of conversion tracts associated with recombination events at the am locus of Neurospora crassa.

In cross B163, heteroallelic am1 am6 and heterozygous for both conventional genetic flanking markers and closer molecular markers, we previously found that the majority on flanker exchanges were remote from events that generated prototrophic recombinants. We report here that natural polymorphisms distinguishing the parents of cross B163 also include sequences within and closely flanking am. Segregation of these markers in B163 prototrophs confirms that the majority of meiotic recombination events at am resulted from gene conversion. Conversion of am6, the distal allele, is more frequent than conversion of am1. Twelve percent of tracts in am6 convertants were discontinuous while 30% of continuous tracts converting am6 extend less than 741 bp.

Long, interrupted conversion tracts initiated by cog in Neurospora crassa.

Multiple polymorphisms distinguish Emerson and Lindegren strains of Neurospora crassa within the histidine-3 gene and in its distal flank. Restriction site and sequence length polymorphism in a set of 14 PCR products covering this 6.9-kb region were used to identify the parental origin of DNA sequence information in prototrophic progeny of crosses heterozygous for auxotrophic mutations in his-3 and the silent sequence differences. Forty-one percent of conversion tracts are interrupted. Where the absence of rec-2+ permits activity of the recombination hotspot cog, conversion appears to originate at cog and conversion tracts are up to 5.9 kb long. The chromosome bearing cog(L), the dominant allele that confers a high frequency of recombination, is almost invariably the recipient of information. In progeny from crosses heterozygous rec-2/rec-2+, conversion tracts are much shorter, most are not initiated at cog and either chromosome seems equally likely to be converted. Although 32% of his-3 prototrophs have a crossover that may be associated with conversion, it is suggested that the apparent association between conversion and crossing over at this locus may be due to confounding of coincidental events rather than to a mechanistic relationship.

Gene conversion alone accounts for more than 90% of recombination events at the am locus of Neurospora crassa.

We have used closely flanking molecular markers located approximately 4 kb distal and 6 kb proximal of the am locus to investigate the incidence of crossover events associated with the generation of prototrophic recombinants in a cross heteroallelic am1 am6. Ninety-three percent of prototrophs were generated by events that did not recombine the molecular markers, indicating that simple conversion accounts for the formation of most prototrophs and that associated crossovers are much less frequent (approximately 0.07) than estimated previously using more distant flanking markers. This suggests that conversion and crossing over during meiosis may arise from distinct mechanisms or that if, as is widely supposed, conversion and crossing over result from alternate modes of resolution of Holliday junctions then, at least for the am locus of Neurospora, the mode of resolution is strongly biased in favor of retaining the parental association of flanking sequences. Because estimates of the association of conversion and crossing over based on more distant gene markers are similar for yeast and Neurospora (approximately 0.35), our observation may have general significance.

The orientation of gene maps by recombination of flanking markers for the am locus of Neurospora crassa.

Fincham (1967), Smyth (1973 b) and Rambosek and Kinsey (1983) have each generated fine-structure maps of the am gene of Neurospora crassa. Each map had a consistent linear order of alleles but the assignment of an orientation with respect to other linkage group-V loci differed. Fincham found the end marked by the am6 allele to be at the distal end of the locus, Smyth found am6 to be at the proximal end while the data of Rambosek and Kinsey did not suggest an orientation. Smyth s orientation has been adopted as the standard, but not unreservedly. We have aligned the genetic and physical maps of the am gene, showing that am6 is at the distal end, supporting Fincham's orientation. However, we suggest that an assumption used to orient fine structure genetic maps is flawed and that the conflicting orientation between these three studies follows from the different choice of flanking markers.