A Homokaryotic Derivative of a Phanerochaete chrysosporium Strain and Its Use in Genomic Analysis of Repetitive Elements

doi:10.1128/AEM.66.4.1629-1633.2000

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Applied and Environmental Microbiology, April 2000, p. 1629-1633, Vol. 66, No. 4
0099-2240/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

A Homokaryotic Derivative of a Phanerochaete chrysosporium Strain and Its Use in Genomic Analysis of Repetitive Elements

Philip Stewart,¹^, Jill Gaskell,² and Daniel Cullen¹^,²^,^*

Department of Bacteriology, University of Wisconsin $---$ Madison, Madison, Wisconsin 53706,¹ and USDA Forest Products Laboratory, Madison, Wisconsin 53705²

Received 2 August 1999/Accepted 20 December 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Analysis of complex gene families in the lignin-degrading basidiomycete Phanerochaete chrysosporium has been hampered by thedikaryotic nuclear condition. To facilitate genetic investigationsin P. chrysosporium strain BKM-F-1767, we isolated a homokaryonfrom regenerated protoplasts. The nuclear condition was establishedby PCR amplification of five unlinked genes followed by probingwith allele-specific oligonucleotides. Under standard nitrogen-limitedculture conditions, lignin peroxidase, manganese peroxidase, andglyoxal oxidase activities of the homokaryon were equivalent tothose of the parental dikaryon. We used the homokaryon to determinethe genomic organization and to assess transcriptional effectsof a family of repetitive elements. Previous studies had identifiedan insertional mutation, Pce1, within lignin peroxidase allelelipI2. The element resembled nonautonomous class II transposonsand was present in multiple copies in strain BKM-F-1767. In thepresent study, three additional copies of the Pce1-like elementwere cloned and sequenced. The distribution of elements was nonrandom;all localized to the same 3.7-Mb chromosome, as assessed by segregationanalysis and Southern blot analysis of the homokaryon. Reversetranscription-PCR (RT-PCR) showed that Pce1 was not spliced fromthe lipI2 transcript in either the homokaryon or the parentaldikaryon. However, both strains had equivalent lignin peroxidaseactivity, suggesting that some lip genes may beredundant.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The most efficient lignin-degrading microorganisms are the white-rot basidiomycetes, of which Phanerochaete chrysosporiumstrain BKM-F-1767 has been the most extensively characterized(18, 25). Under appropriate culture conditions, the fungussecretes multiple isozymes of lignin peroxidase (LiP) and manganeseperoxidase (MnP) as well as of the cellulase cellobiohydrolaseI. These isozymes are encoded by complex families of structurallyrelated genes, although the precise number of genes and the relationshipsamong the sequences have not been determined. Difficulties differentiatingallelic variants from closely related genes and the lack of anaccepted standardized nomenclature have complicated the issue(14).

Allelism could be experimentally resolved if cloning was routinely performed with cultures originating from single basidiospores,which are the homokaryotic products of meiosis. The haploid homokaryonspossess a single nuclear type, in contrast to the two differentnuclear types found in dikaryons. Analyses of single-basidiosporecultures have been used to differentiate alleles and to creategenetic and physical maps of P. chrysosporium (10, 14, 16,23, 27, 28, 31, 33, 36, 37). However, single-basidiosporestrains typically exhibit reduced sporulation, growth rate, andenzyme yields relative to the parental strain (31, 43). Further,chromosome lengths and other aspects of genome organization arenot maintained through meiotic recombination, limiting the experimentalvalue of single-basidiospore strains (10, 13, 23, 37,44). Homokaryons of nonmeiotic origin would greatly simplifyanalysis of complex gene families without the disadvantages incurredbyrecombination.

In addition to the intensively studied gene families, P. chrysosporium contains at least one family of repetitive elements.A 1,747-bp insertional element designated Pce1 was detected inLiP gene lipI2 (15). The element had features common to classII nonautonomous transposons (11, 20), such as inverted terminalrepeats, and a putative target site duplication (TA), and it waspresent in multiple copies in BKM-F-1767 and in other strainsof P. chrysosporium. However, Pce1 contains no extended open readingframes and shows no sequence similarity to known transposases.A single 3.7-Mb chromosome was observed on pulsed-field gel Southernblots probed with Pce1, suggesting a nonrandom distribution ofPce1-like sequences. The number, sequence, insertional context,and genomic organization of the additional Pce1-like sequenceswere not previouslyinvestigated.

Pce1 is inserted immediately adjacent to the fourth intron of lipI2, suggesting that it may be spliced from the mature transcript.Reverse transcription-PCR (RT-PCR) analysis of dikaryotic strainBKM-F-1767 identified a transcript from the wild-type allele,lipI1, but not from Pce1-disrupted lipI2 (15). Thus, in theheterozygous dikaryon, Pce1 transcriptionally inactivates lipI2and is not spliced, as are certain transposons of higher plants(24). However, lipI2 processing in the absence of lipI1 (i.e.,in a homokaryon containing only the lipI2 allele) was not previouslyassessed.

To simplify genetic analyses, we isolated and characterized a homokaryotic derivative of BKM-F-1767. The homokaryon was usedto investigate the organization and transcriptional effects ofPce1-like elements. Four highly conserved elements were sequencedand mapped to a single chromosome. The homokaryon phenotype wassimilar to that of the parental dikaryon even though lipI wastranscriptionally inactivated. The homokaryotic strain will simplifyidentification of new genes in libraries, enhance the resolutionof pulsed-field gels, and aid investigations of chromosome-lengthpolymorphisms.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Fungal strains and isolation of homokaryons. P. chrysosporium BKM-F-1767 was obtained from the Center for Forest Mycology Research, Forest Products Laboratory, Madison,Wis. Single-basidiospore progeny from BKM-F-1767 were describedelsewhere (14).

Homokaryotic strains were isolated from regenerated protoplasts of the dikaryotic strain BKM-F-1767. Protoplasts were preparedessentially as described by Brody and Carbon (7), with minormodifications. A petri plate containing 25 ml of YEG medium (containing[per liter] 5 g of yeast extract and 20 g of glucose) or YMPGmedium (containing [per liter] 2 g of yeast extract, 10 g of maltextract, 2 g of peptone, 10 g of glucose, 2 g of KH₂PO₄, 1 g ofMgSO₄ · 7H₂O, and 1 mg of thiamine) was inoculated with 10⁵ to 10⁷ conidiospores and incubated at 37°C without shaking. After 22h of incubation the medium was removed by aspiration and the myceliawere gently washed with 20 ml of MgOsm buffer (0.5 M MgSO₄, 0.05M maleic acid [pH 5.9]) (3). The mycelium was resuspended inapproximately 12 ml of Novozyme 234 (10 mg of MgOsm buffer perml; Novo Industries, Copenhagen, Denmark) and incubated at 37°Cuntil protoplasts had developed (about 90 min). Protoplasts werefiltered through two layers of Miracloth (Calbiochem, San Diego,Calif.), pelleted, and resuspended in approximately 10 ml of 1.2M sorbitol-10 mM Tris-HCl, pH 7.4. Protoplasts were diluted toapproximately 10³ protoplasts ml¹ in MgOsm buffer, and 10- to 100-µl aliquots were plated on FMSSmedium (17). Plates were incubated at 37°C until colonies werevisible, and then the mycelium was transferred to YMPG plates,which were incubated at 37°C.

Dikaryotic and homokaryotic strains were differentiated by PCR amplification of specific genes. For the initial screeningof 90 colonies, genomic DNA was amplified with lipI-specific primersflanking the Pce1 insertion site (15). The PCR products weresize fractionated on agarose gels and stained with ethidium bromide.Dikaryons were recognized by bands at 2,236 bp and 479 bp, whichcorrespond to lipI2 and lipI1, respectively. Putative homokaryonswere further analyzed by PCR amplification of specific genes followedby Southern blot probing with allele-specific oligonucleotides(14). PCR primers and probes for differentiating alleles oflipE, lipJ, lipF, lipD, and glx were previously reported (14).The mnp2 alleles were amplified as described elsewhere (6)and differentiated with oligonucleotides 5'-GCGATCCTGTAATTGAA-3'and 5'-GCGATGGTGCAACTGGA-3'. Two genes, lipE and lipJ, lie atopposite ends of a LiP gene cluster (36), whereas lipF, lipD,glx, and mnp2 are not linked to the cluster or to each other (14,36).

Culture conditions and enzyme assays. Nitrogen-limited cultures were grown statically at 39°C as described previously (8, 26) and harvested on day 5. LiP activitieswere assayed by veratryl alcohol oxidation (39). MnP activitieswere measured by monitoring the oxidation of 2,6-dimethoxyphenol(Aldrich, Milwaukee, Wis.) at 469 nm (41). Glyoxal oxidase activitywas assayed as described elsewhere (21, 22) using methylglyoxalas the oxidase substrate and phenol red as the substrate for horseradishperoxidase in a coupledassay.

Isolation and mapping of Pce1-like sequences. Pce1-like sequences were cloned from a pWE15-based cosmid library of P. chrysosporium (13) by probing with the full-lengthcopy of Pce1. In some cases, the Universal Genome Walker kit (ClontechLaboratories, Palo Alto, Calif.) was used to clone adjacent regions(34).

Segregation analysis of the Pce1-like sequences was performed on 54 single-basidiospore isolates (14). The flanking regionsof each element were unique, and element-specific PCR primer pairswere designed with one primer anchored in the element and theother in the flanking region. The sequences of these primers wereas follows: Pce2 flanking primer, 5'-CGACAGGCTTGAACATGAC-3'; Pce3flanking primer, 5'-GAGTGTTGACTGCAGCCTTGC-3'; Pce4 flanking primer,5'-CTGCCAGGCAAGCTTCAGAGC-3'; Pce2 and Pce4 element-specific primer,5'-TCAACCCAGGAGCATAG-3'; and Pce3 element-specific primer, 5'-AGCGCTGCAAGACGGTCTGGGATATTG-3'.

Southern blots were used to verify genetic segregation and to establish the nuclear origin of Pce1-like elements. Based onsegregation analysis, the genomic DNA of single-basidiospore culturesharboring one, two, or four elements were digested with XhoI andprobed with nick-translated Pce1 under conditions of high stringency(15). The number and identity of Pce1-like sequences in thehomokaryon RP78 were established similarly. DNA of the parentaldikaryon BKM-F-1767, which contains all the Pce1 copies, was includedas acontrol.

Transcription of lipI2. RT-PCR was used to identify lipI transcripts. Poly(A) RNA was derived from 2-week-old Aspen wood chip cultures, which favorlipI transcription (19). RT was primed with oligo(dT), and PCRconditions were as described previously (19, 40). Three setsof primers were designed to amplify different regions of lipIcDNA, including one set which flanked the Pce1 insert of lipI2(Fig. 1). Primers were based on coding regions conserved in bothalleles and were designated A through F, with sequences as follows:A, 5'-GCGCCTGGTTCGATGTTTTGGATG-3'; B, 5'-CGCCAGGGGTGACGTTGTGCTTCT-3';C, 5'-TCTATCGCTATCTCTCCCGCT-3'; D, 5'-CGGTTCGGGAACAAGGCCATC-3';E, 5'-CAGCTCCAGATGGCCTTGTTCC-3'; and F, 5'-CGCGGGCGATGGTGTGG-3'.Control PCR reactions contained cosmids carrying either lipI1or lipI2. Reactions were run for 35 cycles, as previously reported(37), and the products were size fractionated in agarose gels.Similar studies were also performed using RNA from nitrogen-starvedcultures, in which levels of lipI transcripts are relatively lower(37).

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FIG. 1. Analysis of lipI transcripts. At the top, a schematic representation of lipI alleles shows the locations of introns (black fill), Pce1 (gray fill), and the primers designated A through F (arrows indicate direction of transcription. Ethidium bromide-stained PCR products size fractionated on agarose gels are shown at the bottom. Lanes 1 and 2 are controls, showing amplification products from cosmid templates carrying lipI1 and lipI2, respectively. RT-PCR products from RNA derived from Aspen wood chip cultures inoculated with BKM-F-1767 and RP-78 are shown in lanes 3 and 4, respectively. No RT-PCR amplification product was obtained from the RP-78 RNA (lane 4). In contrast, BKM-F-1767 cultures contained the expected lipI transcript (lane 3). The sizes of the PCR products (in nucleotides) are shown on the left.

Sequence analysis. Nucleotide sequences were determined with the ABI Prism Dye Terminator Cycle Sequencing kit (Perkin-Elmer Applied Biosystems,Foster City, Calif.) with an ABI373 DNA sequencer. Nucleotideand amino acid sequence similarity searches used the BLAST method(5) on the National Center for Biotechnology Informationdatabases.

Nucleotide sequence accession numbers. The elements designated Pce2, Pce3, and Pce4, together with a >900-bp flanking region for each, were assigned GenBank accessionnumbers AF134289, AF134290, and AF134291,respectively.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Isolation and characterization of homokaryon RP-78. Homokaryotic derivatives of BKM-F-1767 were isolated from regenerated protoplasts, a strategy successfully used for otherbasidiomycetes (1, 12, 29, 35). In contrast to theseprevious studies, homokaryons and dikaryons cannot be simply differentiatedbecause P. chrysosporium hyphae lack clamp connections (9)and the mating system is not well defined (4, 38).

We identified homokaryons through PCR amplification and allele-specific hybridization techniques. PCR amplification of thedimorphic lipI alleles (lipI2 is disrupted by Pce1 and is therefore1,747 bp larger than lipI1) was used to distinguish between homokaryonsand dikaryons. On this basis, approximately 50% of the 90 regeneratedprotoplasts were judged dikaryotic and discarded (data not shown).Allele-specific probing of five unlinked genes confirmed thatthe remaining isolates were all homokaryotic but of the same nucleartype. The existence of a deleterious or lethal allele(s) wouldmost easily explain our inability to recover the second nucleartype.

One homokaryotic isolate, RP-78, was characterized further. In addition to lipI, the precise alleles of five unlinked geneswere determined using allele-specific oligonucleotide probes (Fig.2). Under standard N-limited culture conditions, MnP, LiP, andglyoxal oxidase activities of RP-78 were similar to those of theparental strain, BKM-F-1767 (Table 1). On YMPG agar, RP-78 wasslower growing but produced more asexual spores than the parent(Table 1).

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FIG. 2. Southern blot analysis of six PCR amplified genes, demonstrating the homokaryotic nature of RP-78. For each gene, two identical gels were run, with BKM-F-1767 PCR products in the left lanes and RP-78 products in the right. Each gel was then blotted to Nytran and probed with an allele-specific oligonucleotide. The blots show both alleles present in the dikaryotic strain BKM-F-1767 but only a single allele present in RP-78. PCR product sizes were as follows: lipE, 1,535 nucleotides (nt); lipJ, 675 nt; lipF, 1,480 nt; lipD, 440 nt; glx, 680 nt; and mnp2, 1,509 nt.

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TABLE 1. Enzyme activities and growth characteristics of dikaryotic (BKM-F-1767) and homokaryotic (RP-78) strains

Genomic organization of the Pce1 family. We cloned three additional Pce1-like sequences designated Pce2, Pce3, and Pce4. Analysis of flanking regions revealed no extendedopen reading frames and no significant similarity to databasesequences. Surprisingly, the three new elements had at least 98%nucleotide identity with Pce1. The inverted terminal repeats wereidentical among the four Pce1 sequences, but they were imperfect,with 25 of 32 bases conserved in Pce2, Pce3, and Pce4. In short,all four sequences appeared to be the same nonautonomous classIIelement.

Pce1, Pce2, and Pce3 were linked (Fig. 3), but except for Pce1, none were closely linked to genes involved in lignocellulosedegradation. Pce4 was not linked to the other three elements.Because the nucleotide sequences are highly conserved, all wouldbe expected to strongly cross-hybridize under moderate stringency.Thus, the pattern of a previously published pulsed-field gel blotshowing hybridization solely to a 3.7-Mb band (15) can be attributedto localization of all Pce1-like sequences to a single sisterchromosome. Further confirming these results, Southern blots ofXhoI-digested genomic DNA from RP-78 showed the presence of allfour Pce1-like elements (data not shown).

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FIG. 3. Genetic linkage of Pce1, Pce2, and Pce3 and their relationship to the LiP gene cluster. Linkage was based on analyses of 54 single-basidiospore cultures. Vertical arrows indicate positions of elements. Thickened horizontal arrows show transcriptional orientation of LiP genes (36). Pce4 segregated independently.

Transcription of lipI2. Under conditions favoring lipI expression (19), RT-PCR showed the presence of lipI transcripts in the dikaryotic parentBKM-F-1767 but not in RP-78 (Fig. 1). Conceivably, a Pce1-containingtranscript might not be efficiently reverse transcribed and PCRamplified. To minimize this possibility, three sets of primerswere used, including two which did not flank the insertion (resultsfor primers A plus B and E plus F are shown in Fig. 1). The identityof the lipI cDNAs (Fig. 1, lane 3) was confirmed by direct sequencing,and identical results were obtained when RP-78 was grown in nitrogen-starveddefined medium (data notshown).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Protoplast-derived homokaryons, termed "protoclones" by Sonnenberg et al. (35), have been identified by other means fromother basidiomycetes (1, 12, 29, 35). The nucleus ofP. chrysosporium protoclone RP-78 is genetically identical toa single nucleus of the dikaryotic strain BKM-F-1767, from whichit was derived. RP-78 is genetically distinct from single-basidiosporecultures, which are also homokaryotic but have undergone meioticrecombination. The use of RP-78 should facilitate gene cloning,mutagenesis studies, and additional studies on the genetic mechanismscontrolling variation in ligninolytic activity. For example, identifyingnew members of gene families, either from conventional librariesor by PCR amplification, will be greatly simplified because questionsof allelism can be excluded. Pulsed-field gel analysis using RP-78could avoid dimorphic sister chromosomes (10, 13, 23, 37)and thereby result in improved bandresolution.

RP-78 is similar to BKM-F-1767 in its ligninolytic enzyme activity (Table 1) and biomechanical pulping performance (2;D. Dietrich, J. Gaskell, M. Akhtar, R. Blanchette, and D. Cullen,unpublished data). Interestingly, RP-78 LiP activity is approximatelythe same as that of BKM-F-1767 although it lacks a transcriptionallyactive lipI allele. This observation suggests that LiP activityis influenced by multiple factors and supports the hypothesisthat LiP genes areredundant.

Previous Southern blot analysis of BKM-F-1767 suggested multiple Pce1-like sequences, and a strong signal was assigned toa single chromosome band of 3.7 Mb (15). Eight lip genes alsoreside on this chromosome and its dimorphic homologue of 3.5 Mb(36). Because of the Pce family's unusual distribution, theprospect of isolating an active transposon, and the possibilitythat other functional genes might be disrupted, three additionalPce1-like elements were cloned, sequenced, andmapped.

All four members of the Pce family were over 98% identical to each other, an unexpected result because none have extendedopen reading frames (the largest being 155 amino acids). The observedsequence conservation suggests these elements have arisen relativelyrecently. The Pce family may represent the inactive remnants ofa transposable element. Approximately 15 copies of the 437-bpelement, vader, are present in the Aspergillus niger genome, whiletheir progenitor, Tan1, a 2.3-kb active transposon, is presentas a single copy (30). Although no active progenitor of Pcewas detected in P. chrysosporium, the possibility of some biologicalactivity for the Pce sequences cannot beexcluded.

Segregation analysis showed that Pce1, Pce2, and Pce3 were linked. While Pce4 was localized to the same chromosome, the distancewas such that it appeared unlinked. Formally, the possibilityof comigrating 3.7-Mb chromosomes (one with Pce4 and the otherwith Pce1, Pce2, and Pce3) cannot be dismissed. However, thisseems unlikely because none of the more than 25 genes that havebeen genetically and physically mapped to date (14; S. Alsop,B. Janse, J. Gaskell, A. Vanden Wymelenberg, M. Vallim, and D.Cullen, unpublished data) reside on nonhomologous 3.7-Mb chromosomes.Moreover, Pce4 clearly cosegregates in the homokaryon RP-78.

The nonrandom distribution of eukaryotic repetitive sequences has been explained by a variety of mechanisms, including site-specificinsertions and unequal crossover events between repetitive elements(32, 42). Site-specific insertion, either by specific sequencesor by recognition of particular physical characteristics of certainregions of the genome, is not compatible with the available datafor the Pce family. Over 900 bp flanking each Pce insertion sitewere sequenced, and no obvious similarity wasdetected.

Unequal crossover between repetitive sequences may be the simplest explanation for the unusual organization of the Pce family.Repetitive sequences (such as transposable elements or highlysimilar gene families) may function as small regions of homologyfor recombination to occur (44). Unequal crossover between sisterchromosomes would generate a duplication in one and a deletionin the other. Thus, mechanisms that may enrich the Pce familyon a single sister chromosome may also contribute to the observedchromosome length dimorphism. Arguing against this hypothesis,however, the regions surrounding insertion sites for all membersof the Pce family appear to be conserved on both homologues (datanot shown). No duplications or deletions were detected on eitherhomologue. Nevertheless, the Pce1 family directly contributesto the observed length dimorphism, albeit a small proportion (~8of ~200 kb). Conceivably, other repetitive sequences may be distributedon the 3.7-Mbhomologue.

In conclusion, homokaryon RP-78 was isolated from regenerated protoplasts and shown to be phenotypically similar to its dikaryoticparent, BKM-F-1767. Both RP-78 and BKM-F-1767 contain four copiesof the nonautonomous class II transposon Pce, all of which mappedto a 3.7-Mb chromosome. The lipI2 gene of RP-78 has been transcriptionallyinactivated by Pce1 insertion but retains LiP activity equivalentto that of the dikaryon, suggesting that some lip genes are redundant.We anticipate that RP-78 will be useful for a variety of geneticanalyses, especially differentiating new members of complex genefamilies.

	ACKNOWLEDGMENT

This work was supported by Department of Energy grant DE-FG02-87ER13712.

	FOOTNOTES

^* Corresponding author. Mailing address: Forest Products Laboratories, One Gifford Pinchot Dr., Madison, WI 53705. Phone: (608)231-9468. Fax: (608) 231-9488. E-mail: dcullen{at}facstaff.wisc.edu.

Present address: Rocky Mountain Laboratories, NIAID, NIH, Hamilton, MT59840.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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28. Li, B., and V. Renganathan. 1998. Gene cloning and characterization of a novel cellulose-binding $beta$ -glucosidase from Phanerochaete chrysosporium. Appl. Environ. Microbiol. 64:2748-2754[Abstract/Free Full Text].

29. Matsumoto, T., Y. Fukumasa-Nakai, and M. Komatsu. 1995. Efficient dedikaryotization of higher basidiomycetes by the protoplast regeneration method. Rep. Tottori Mycol. Inst. 33:29-33.

30. Nyyssonen, E., M. Amutan, L. Enfield, J. Stubbs, and N. Dunn-Coleman. 1996. The transposable element Tan1 of Aspergillus niger var. awamori, a new member of the Fot1 family. Mol. Gen. Genet. 253:50-56[CrossRef][Medline].

31. Raeder, U., W. Thompson, and P. Broda. 1989. Genetic factors influencing lignin peroxidase activity in Phanerochaete chrysosporium ME446. Mol. Microbiol. 3:919-924[CrossRef][Medline].

32. SanMiguel, P., A. Tikhonov, Y.-K. Jin, N. Motchoulskaia, D. Zakharov, A. Melake-Berhan, P. S. Springer, K. J. Edwards, M. Lee, Z. Avramova, and J. L. Bennetzen. 1996. Nested retrotransposons in the intergenic regions of the maize genome. Science 274:765-768[Abstract/Free Full Text].

33. Schalch, H., J. Gaskell, T. L. Smith, and D. Cullen. 1989. Molecular cloning and sequences of lignin peroxidase genes of Phanerochaete chrysosporium. Mol. Cell. Biol. 9:2743-2747[Abstract/Free Full Text].

34. Siebert, P., D. Chenchik, D. Kellogg, K. Lukyanov, and S. Lukyanov. 1995. An improved PCR method for walking in uncloned genomic DNA. Nucleic Acids Res. 23:1087-1088[Free Full Text].

35. Sonnenberg, A., J. G. Wessels, and L. J. van Griensven. 1988. An efficient protoplasting/regeneration system for Agaricus bisporus and Agaricus bitorquis. Curr. Microbiol. 17:285-291[CrossRef].

36. Stewart, P., and D. Cullen. 1999. Organization and differential regulation of a cluster of lignin peroxidase genes of Phanerochaete chrysosporium. J. Bacteriol. 181:3427-3432[Abstract/Free Full Text].

37. Stewart, P., P. Kersten, A. Vanden Wymelenberg, J. Gaskell, and D. Cullen. 1992. The lignin peroxidase gene family of Phanerochaete chrysosporium: complex regulation by carbon and nitrogen limitation, and the identification of a second dimorphic chromosome. J. Bacteriol. 174:5036-5042[Abstract/Free Full Text].

38. Thompson, W., and P. Broda. 1987. Mating behavior in an isolate of Phanerochaete chrysosporium. Trans. Br. Mycol. Soc. 89:285-294.

39. Tien, M., and T. K. Kirk. 1984. Lignin-degrading enzyme from Phanerochaete chrysosporium: purification, characterization, and catalytic properties of a unique H₂O₂-requiring oxygenase. Proc. Natl. Acad. Sci. USA 81:2280-2284[Abstract/Free Full Text].

40. Vallim, M., B. Janse, J. Gaskell, A. Pizzirani-Kleiner, and D. Cullen. 1998. Phanerochaete chrysosporium cellobiohydrolase and cellobiose dehydrogenase transcripts in wood. Appl. Environ. Microbiol. 64:1924-1928[Abstract/Free Full Text].

41. Wariishi, H., K. Valli, and M. H. Gold. 1992. Mn oxidation by manganese peroxidase from Phanerochaete chrysosporium: kinetic mechanisms and role of chelators. J. Biol. Chem. 267:23688-23695[Abstract/Free Full Text].

42. Wichman, H. A., R. A. Van Den Bussche, M. J. Hamilton, and R. J. Baker. 1992. Transposable elements and the evolution of genome organization in mammals. Genetica 86:287-293[CrossRef][Medline].

43. Wyatt, A. M., and P. Broda. 1995. Informed strain improvement for lignin degradation by Phanerochaete chrysosporium. Microbiology 141:2811-2822[Abstract].

44. Zolan, M. 1995. Chromosome-length polymorphisms in fungi. Microbiol. Rev. 59:686-698[Abstract/Free Full Text].

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28.	Li, B., and V. Renganathan. 1998. Gene cloning and characterization of a novel cellulose-binding $beta$ -glucosidase from Phanerochaete chrysosporium. Appl. Environ. Microbiol. 64:2748-2754[Abstract/Free Full Text].
29.	Matsumoto, T., Y. Fukumasa-Nakai, and M. Komatsu. 1995. Efficient dedikaryotization of higher basidiomycetes by the protoplast regeneration method. Rep. Tottori Mycol. Inst. 33:29-33.
30.	Nyyssonen, E., M. Amutan, L. Enfield, J. Stubbs, and N. Dunn-Coleman. 1996. The transposable element Tan1 of Aspergillus niger var. awamori, a new member of the Fot1 family. Mol. Gen. Genet. 253:50-56[CrossRef][Medline].
31.	Raeder, U., W. Thompson, and P. Broda. 1989. Genetic factors influencing lignin peroxidase activity in Phanerochaete chrysosporium ME446. Mol. Microbiol. 3:919-924[CrossRef][Medline].
32.	SanMiguel, P., A. Tikhonov, Y.-K. Jin, N. Motchoulskaia, D. Zakharov, A. Melake-Berhan, P. S. Springer, K. J. Edwards, M. Lee, Z. Avramova, and J. L. Bennetzen. 1996. Nested retrotransposons in the intergenic regions of the maize genome. Science 274:765-768[Abstract/Free Full Text].
33.	Schalch, H., J. Gaskell, T. L. Smith, and D. Cullen. 1989. Molecular cloning and sequences of lignin peroxidase genes of Phanerochaete chrysosporium. Mol. Cell. Biol. 9:2743-2747[Abstract/Free Full Text].
34.	Siebert, P., D. Chenchik, D. Kellogg, K. Lukyanov, and S. Lukyanov. 1995. An improved PCR method for walking in uncloned genomic DNA. Nucleic Acids Res. 23:1087-1088[Free Full Text].
35.	Sonnenberg, A., J. G. Wessels, and L. J. van Griensven. 1988. An efficient protoplasting/regeneration system for Agaricus bisporus and Agaricus bitorquis. Curr. Microbiol. 17:285-291[CrossRef].
36.	Stewart, P., and D. Cullen. 1999. Organization and differential regulation of a cluster of lignin peroxidase genes of Phanerochaete chrysosporium. J. Bacteriol. 181:3427-3432[Abstract/Free Full Text].
37.	Stewart, P., P. Kersten, A. Vanden Wymelenberg, J. Gaskell, and D. Cullen. 1992. The lignin peroxidase gene family of Phanerochaete chrysosporium: complex regulation by carbon and nitrogen limitation, and the identification of a second dimorphic chromosome. J. Bacteriol. 174:5036-5042[Abstract/Free Full Text].
38.	Thompson, W., and P. Broda. 1987. Mating behavior in an isolate of Phanerochaete chrysosporium. Trans. Br. Mycol. Soc. 89:285-294.
39.	Tien, M., and T. K. Kirk. 1984. Lignin-degrading enzyme from Phanerochaete chrysosporium: purification, characterization, and catalytic properties of a unique H₂O₂-requiring oxygenase. Proc. Natl. Acad. Sci. USA 81:2280-2284[Abstract/Free Full Text].
40.	Vallim, M., B. Janse, J. Gaskell, A. Pizzirani-Kleiner, and D. Cullen. 1998. Phanerochaete chrysosporium cellobiohydrolase and cellobiose dehydrogenase transcripts in wood. Appl. Environ. Microbiol. 64:1924-1928[Abstract/Free Full Text].
41.	Wariishi, H., K. Valli, and M. H. Gold. 1992. Mn oxidation by manganese peroxidase from Phanerochaete chrysosporium: kinetic mechanisms and role of chelators. J. Biol. Chem. 267:23688-23695[Abstract/Free Full Text].
42.	Wichman, H. A., R. A. Van Den Bussche, M. J. Hamilton, and R. J. Baker. 1992. Transposable elements and the evolution of genome organization in mammals. Genetica 86:287-293[CrossRef][Medline].
43.	Wyatt, A. M., and P. Broda. 1995. Informed strain improvement for lignin degradation by Phanerochaete chrysosporium. Microbiology 141:2811-2822[Abstract].
44.	Zolan, M. 1995. Chromosome-length polymorphisms in fungi. Microbiol. Rev. 59:686-698[Abstract/Free Full Text].