A chromosome rearrangement of Neurospora that produces viable progeny containing two nucleolus organizers

Segregation of heterogeneous rDNA segments during demagnification of a Neurospora crassa strain possessing a double nucleolar organizer

We have produced a duplication strain of Neurospora crassa, DpAR33-PR-6, which contains two cytologically visible nucleoli (a DNO or double nucleolar organizer strain). When freshly generated, this strain has approximately twice the number of rRNA cistrons found in the parental (single nucleolar organizer) strains. After several serial propagations, there is a marked reduction in rRNA cistron number, approximating that of the SNO parental strains. This reduction in rRNA cistrons ("demagnification") was not achieved by breakdown of the VL→IVL translocation used to generate the duplication, as rDNA from the two parents can be distinguished by the size of the non-transcribed spacer region in the rDNA repeat unit of each strain. rDNA characteristic of both parents is present even after demagnification, in approximately equal amounts, suggesting the rRNA cistrons are lost randomly and non-preferentially from each homologous chromatid. In addition, the steady-state growth rate appears to be affected by rRNA cistron number, decreasing in freshly generated DNO strains relative to the parental strains, and returning to parental levels after demagnification.

Neurospora as a model fungus for studies in cytogenetics and sexual biology at Stanford

Dodge's early work (1927-1940) on Neurospora genetics and sexual biology inspired Beadle and Tatum at Stanford to use N.crassa for their landmark discovery that genes specify enzymes. Neurospora has since become a model organism for numerous genetic, cytogenetic, biochemical, molecular and population biology studies. Neurospora is haploid in the vegetative phase with a transient diploid sexual phase. Its meiotic cells (asci) are large, allowing easy examination of dividing nuclei and chromosomes under a light microscope. The haploid meiotic products are themselves the sexual progeny that grow into vegetative cultures, thus avoiding the cumbersome testcrosses and complex dominance -recessive relationships, as in diploid organisms.The Perkins'laboratory at Stanford (1949-2007) played a pivotal role in advancing our knowledge of Neurospora genetics, sexual biology, cytogenetics and population biology. Since 1974, I have taken advantage of various chromosome-staining methods to examine ascus and ascospore development in wild type and in numerous mutant strains. In addition,I have used GFP-tagged genes to visualize the expression or silencing of unpaired genes in a post-transcriptional gene silencing process (meiotic silencing by unpaired DNA) that operates specifically during meiosis. The genome of N. crassa contains over 10 000 protein- coding genes. Gene knockouts or mutations in specific sequences may now be readily correlated with the observed cytological defects in the sexual stage, thus advancing our molecular understanding of complex processes during ascus and ascospore development.

Chromosome rearrangements in Neurospora and other filamentous fungi

Knowledge of fungal chromosome rearrangements comes primarily from N. crassa, but important information has also been obtained from A. nidulans and S. macrospora. Rearrangements have been identified in other Sordaria species and in Cochliobolus, Coprinus, Magnaporthe, Podospora, and Ustilago. In Neurospora, heterozygosity for most chromosome rearrangements is signaled by the appearance of unpigmented deficiency ascospores, with frequencies and ascus types that are characteristic of the type of rearrangement. Summary information is provided on each of 355 rearrangements analyzed in N. crassa. These include 262 reciprocal translocations, 31 insertional translocations, 27 quasiterminal translocations, 6 pericentric inversions, 1 intrachromosomal transposition, and numerous complex or cryptic rearrangements. Breakpoints are distributed more or less randomly among the seven chromosomes. Sixty of the rearrangements have readily detected mutant phenotypes, of which half are allelic with known genes. Constitutive mutations at certain positively regulated loci involve rearrangements having one breakpoint in an upstream regulatory region. Of 11 rearrangements that have one breakpoint in or near the NOR, most appear genetically to be terminal but are in fact physically reciprocal. Partial diploid strains can be obtained as recombinant progeny from crosses heterozygous for insertional or quasiterminal rearrangements. Duplications produced in this way precisely define segments that cover more than two thirds of the genome. Duplication-producing rearrangements have many uses, including precise genetic mapping by duplication coverage and alignment of physical and genetic maps. Typically, fertility is greatly reduced in crosses parented by a duplication strain. The finding that genes within the duplicated segment have undergone RIP mutation in some of the surviving progeny suggests that RIP may be responsible for the infertility. Meiotically generated recessive-lethal segmental deficiencies can be rescued in heterokaryons. New rearrangements are found in 10% or more of strains in which transforming DNA has been stably integrated. Electrophoretic separation of rearranged chromosomal DNAs has found useful applications. Synaptic adjustment occurs in inversion heterozygotes, leading progressively to nonhomologous association of synaptonemal complex lateral elements, transforming loop pairing into linear pairing. Transvection has been demonstrated in Neurospora. Beginnings have been made in constructing effective balancers. Experience has increased our understanding of several phenomena that may complicate analysis. With some rearrangements, nondisjunction of centromeres from reciprocal translocation quadrivalents results in 3:1 segregation and produces asci with four deficiency ascospores that occupy diagnostic positions in linear asci. Three-to-one segregation is most frequent when breakpoints are near centromeres. With some rearrangements, inviable deficiency ascospores become pigmented. Diagnosis must then depend on ascospore viability. In crosses between highly inbred strains, analysis may be handicapped by random ascospore abortion. This is minimized by using noninbred strains as testers.

Cytogenetics of an intrachromosomal transposition in Neurospora

Knowledge of intrachromosomal transpositions has until now been primarily cytological and has been limited to Drosophila and to humans, in both of which segmental shifts can be recognized by altered banding patterns. There has been little genetic information. In this study, we describe the genetic and cytogenetic properties of a transposition in Neurospora crassa. In Tp(IR-->IL)T54M94, a 20 map unit segment of linkage group I has been excised from its normal position and inserted near the centromere in the opposite arm, in inverted order. In crosses heterozygous for the transposition, about one-fifth of surviving progeny are duplications carrying the transposed segment in both positions. These result from crossing over in the interstitial region. There is no corresponding class of progeny duplicated for the interstitial segment. The duplication strains are barren in test crosses. A complementary deficiency class is represented by unpigmented, inviable ascospores. Extent of the duplication was determined by duplication-coverage tests. Orientation of the transposed segment was determined using Tp x Tp crosses heterozygous for markers inside and outside the transposed segment, and position of the insertion relative to the centromere was established using quasi-ordered half-tetrads from crosses x Spore killer. Quelling was observed in the primary transformants that were used to introduce a critical marker into the transposed segment by repeat-induced point mutation (RIP).

Magnification of rRNA gene number in a Neurospora crassa strain with a partial deletion of the nucleolus organizer

Some progeny from crosses between the Neurospora crassa translocation strain T(IL----VL)OY321 and normal sequence N. crassa strains are duplication strains with a partial deletion of the nucleolus organizer. Despite the deletion, these progeny are viable and produce a functional nucleolus. Quantification of rRNA gene number in these deletion progeny demonstrated a significant loss of rRNA genes, down to 60% of the parental wild-type level. Initially, all of these reduced nucleolus organizer (RNO) strains demonstrated a reduction in the rate of mycelial elongation in growth tubes. After several vegetative growth cycles some progeny reverted to the normal growth phenotype, and also showed an increase in the number of rRNA genes to approximately that of the wild type.

Spontaneous IR duplications generated at mitosis in Aspergillus nidulans: further evidence of a preferential site of transposed attachment

A radiation-induced translocation, T(IIR----IIIL), has been shown to be nonreciprocal and to have most of IIR, including its terminus, attached uninverted to the terminus of IIIL.--Progeny with the IIR segment in duplicate, obtained from crosses of T(IIR----IIIL) to strains with a standard genome, were unstable at mitosis; like earlier duplication strains, they suffered deletions from either duplicate segment. Frequent mitotic crossing over occurred between the duplicate IIR segments so that, following deletions, more than two classes of stable, balanced products arose from each heterozygous duplication strain.-- Spontaneous, mitotically arising duplications of the IR segment, bearing the rate-limiting adE20 allele, can be selected on adenine-free medium on which they emerge as vigorous sectors from the stunted adE20 colony. It was shown previously that most such duplications, when selected from a strain with standard genome, had the terminal IR segment attached to the end of IIR. Selection has now been made from an adE20 strain carrying T(IIR----IIIL), and seven of the 13 independent IR duplications were linked to the III-IIR translocation complex. In three strains analyzed further, the duplicate IR segments, which included the IR terminus, were attached uninverted to the terminus of IIR; the segments of IR were of approximately equal genetic length.--This supports earlier suggestions that there is a preferential site for the initiation of IR duplications and a preferential site, the IIR terminus, for their attachment.

A chromosome rearrangement in Neurospora that produces segmental aneuploid progeny containing only part of the nucleolus organizer

In translocation T (IL leads to VL) OY321 of Neurospora crassa a distal portion of the nucleolus organizer chromosome, including ribosomal DNA sequences and the nucleolus satellite, is interchanged with a long terminal segment of IL. When OY321 is crossed by Normal sequence, one-fourth of the meiotic products are segmental aneuploids that contain two copies of the long IL segment and that are deficient for the distal portion of the organizer. Each such product forms a nucleolus and is viable. The complementary aneuploid products are deficient for the IL segment and are therefore inviable. - In crosses of OY321 X OY321, each product is capable of making two nucleoli; nucleoli formed by the separated nucleolus organizer parts usually fuse, but most 8-spored asci contain some nuclei in which two separate nucleoli can be seen. One nucleolus is then terminal on its chromosome while the second is interstitial and somewhat smaller. - In crosses of OY321 X Normal, half of the meiotic products are capable of making two nucleoli. However, only about 15% of 8-spored asci have one or more nuclei containing separate nucleoli. At pachytene and later in prophase I, the single fusion nucleolus is associated with three bivalent chromosome segments. Each nucleus of every ascus contains at least one nucleolus, even in asci where some nuclei display two nucleoli. - Crosses of Aneuploid X Normal are usually semibarren, producing a reduced number of ascospores, some of which are inviable. Some aneuploid cultures become fully fertile by reverting to a quasinormal sequence lacking a satellite. In some crosses of Aneuploid X Normal, individual asci may show at prophase I either complete loss, partial loss, or pycnosis of the translocated IL segment. This observation of pycnosis suggests chromosome inactivation. - Growth from aneuploid ascospores is initially slow, but can accelerate to the wild-type rate.

Conventional and unconventional analysis of an inversion in Neurospora

In(IL; IR)O Y348is a pericentric inversion of linkage group I inN. crassa, with a breakpoint betweenfrandun-5in the left arm and a breakpoint betweenad-9andnit-1in the right arm. Approximate breakpoint location was found by tabulating crossovers between the rearrangement and markers in normal chromosome sequence. Inversion structure was verified by markedIn O Y348×In O Y348crosses. Precise mapping of breakpoints was by duplication coverage. Inversions likeO Y348do not produce progeny with segmental chromosome duplications when crossed to normal sequence, but duplications were produced by crossing it toIn(IL; IR)O Y323(Barry & Leslie, 1982), another standard pericentric inversion, and toT(I → VI)NM103(Turner, 1977), a translocation to a tip. Each of these rearrangements has a breakpoint within the inverted region ofIn O Y348. Two duplications fromIn O Y348×In O Y323were converted to normal chromosome sequence by double mitotic recombination. Besides expediting mapping, the technique of intercrossing rearrangements increasingly enables us to make segmental duplications exactly tailored for studying specific included genes.

Regulation of ribosomal RNA cistron number in a strain of Neurospora crassa with a duplication of the nucleolus organizer region

Some progeny from a cross of the translocation mutant T(VL leads to IVL)AR33 with wild-type Neurospora crassa are double nucleolus organizer (DNO) strains, usually displaying two distinct nucleolus organizer regions. The DNO strain is sterile but displays the same growth response as normal laboratory strains of Neurospora. We used DNA-DNA hybridization techniques to quantify the number of rRNA cistrons in the DNO mutant and its vegetative progeny. Comparisons of the rate of hybridization of genomic DNA from the parental AR33 strain and from the DNO strain showed that hybridization was more rapid for the DNO strain than for the parental strain. Successive vegetative progeny of the DNO strain displayed hybridization rates intermediate to those of the original DNO strain and the parental single nucleolus strain, indicating that the number of rRNA cistrons had decreased during vegetative propagation. Estimates of rRNA cistron number obtained from comparisons of the amount of single copy DNA and rDNA hybridized to genomic DNO and AR33 DNA at saturation indicate that the parental AR33 strain contains 225 copies of the rRNA repeat unit while the DNO strain has approx. 440 copies. The number of rRNA cistrons decreases gradually in the successive vegetative progeny, approximating the parental haploid value by the eleventh vegetative transfer.