Identification of a Third Sulfate Activation System in Sinorhizobium sp. Strain BR816: the CysDN Sulfate Activation Complex

Sinorhizobium sp. strain BR816 possesses two nodPQ copies, providing activated sulfate (3′-phosphoadenosine-5′-phosphosulfate [PAPS]) needed for the biosynthesis of sulfated Nod factors. It was previously shown that the Nod factors synthesized by a nodPQ double mutant are not structurally different from those of the wild-type strain. In this study, we describe the characterization of a third sulfate activation locus. Two open reading frames were fully characterized and displayed the highest similarity with the Sinorhizobium meliloti housekeeping ATP sulfurylase subunits, encoded by the cysDN genes. The growth characteristics as well as the levels of Nod factor sulfation of a cysD mutant (FAJ1600) and a nodP1 nodQ2 cysD triple mutant (FAJ1604) were determined. FAJ1600 shows a prolonged lag phase only with inorganic sulfate as the sole sulfur source, compared to the wild-type parent. On the other hand, FAJ1604 requires cysteine for growth and produces sulfate-free Nod factors. Apigenin-induced nod gene expression for Nod factor synthesis does not influence the growth characteristics of any of the strains studied in the presence of different sulfur sources. In this way, it could be demonstrated that the “household” CysDN sulfate activation complex of Sinorhizobium sp. strain BR816 can additionally ensure Nod factor sulfation, whereas the symbiotic PAPS pool, generated by the nodPQ sulfate activation loci, can be engaged for sulfation of amino acids. Finally, our results show that rhizobial growth defects are likely the reason for a decreased nitrogen fixation capacity of bean plants inoculated with cysD mutant strains, which can be restored by adding methionine to the plant nutrient solution.     

Nod factors of Rhizobium are a key to the legume door

Symbiotic interactions between rhizobia and legumes are largely controlled by reciprocal signal exchange. Legume roots excrete flavonoids which induce rhizobial nodulation genes to synthesize and excrete lopo-oligosaccharide Nod factors. In turn, Nod factors provoke deformation of the root hairs and nodule primordium formation. Normally, rhizobia enter roots through infection threads in markedly curled root hairs. If Nod factors are responsible for symbiosis-specific root hair deformation, they could also be the signal for entry of rhizobia into legume roots. We tested this hypothesis by adding, at inoculation, NodNGR-factors to signal-production-deficient mutants of the broad-host-range Rhizobium sp. NGR234 and Bradyrhizobium japorticum strain USDA110. Between 10 ⁻⁷ M and 10⁻⁶ M NodNGR factors permitted these NodABC mutants to penetrate, nodulate and fix nitrogen on Vigna unguiculata and Glycine max, respectively. NodNGR factors also allowed Rhizobium fredii strain USDA257 to enter and fix nitrogen on Calopogonium caeruleum, a non-host. Detailed cytological investigations of V. unguiculata showed that the NodABC mutant UGR AnodABC, in the presence of NodNGR factors, entered roots in the same way as the wild-type bacterium. Since infection threads were also present in the resulting nodules, we conclude that Nod factors are the signals that permit rhizobia to penetrate legume roots via infection threads.     

Symbiotic properties and first analyses of the genomic sequence of the fast growing model strain Sinorhizobium fredii HH103 nodulating soybean

Glycine max (soybean) plants can be nodulated by fast-growing rhizobial strains of the genus Sinorhizobium as well as by slow-growing strains clustered in the genus Bradyrhizobium. Fast-growing rhizobia strains with different soybean cultivar specificities have been isolated from Chinese soils and from other geographical regions. Most of these strains have been clustered into the species Sinorhizobium fredii. The S. fredii strain HH103 was isolated from soils of Hubei province, Central China and was first described in 1985. This strain is capable to nodulate American and Asiatic soybean cultivars and many other different legumes and is so far the best studied fast-growing soybean-nodulating strain. Additionally to the chromosome S. fredii HH103 carries five indigenous plasmids. The largest plasmid (pSfrHH103e) harbours genes for the production of diverse surface polysaccharides, such as exopolysaccharides (EPS), lipopolysaccharides (LPS), and capsular polysaccharides (KPS). The second largest plasmid (pSfrHH103d) is a typical symbiotic plasmid (pSym), carrying nodulation and nitrogen fixation genes. The present mini review focuses on symbiotic properties of S. fredii HH103, in particular on nodulation and surface polysaccharides aspects. The model strain S. fredii HH103 was chosen for genomic sequencing, which is currently in progress. First analyses of the draft genome sequence revealed an extensive synteny between the chromosomes of S. fredii HH103 and Rhizobium sp. NGR234.     

Nod factor requirements for efficient stem and root nodulation of the tropical legume Sesbania rostrata

Azorhizobium caulinodans ORS571 synthesizes mainly pentameric Nod factors with a household fatty acid, an N-methyl, and a 6-O-carbamoyl group at the nonreducing-terminal residue and with a d-arabinosyl, an l-fucosyl group, or both at the reducing-terminal residue. Nodulation on Sesbania rostrata was carried out with a set of bacterial mutants that produce well characterized Nod factor populations. Purified Nod factors were tested for their capacity to induce root hair formation and for their stability in an in vitro degradation assay with extracts of uninfected adventitious rootlets. The glycosylations increased synergistically the nodulation efficiency and the capacity to induce root hairs, and they protected the Nod factor against degradation. The d-arabinosyl group was more important than the l-fucosyl group for nodulation efficiency. Replacement of the 6-O-l-fucosyl group by a 6-O-sulfate ester did not affect Nod factor stability, but reduced nodulation efficiency, indicating that the l-fucosyl group may play a role in recognition. The 6-O-carbamoyl group contributes to nodulation efficiency, biological activity, and protection, but could be replaced by a 6-O-acetyl group for root nodulation. The results demonstrate that none of the studied substitutions is strictly required for triggering normal nodule formation. However, the nodulation efficiency was greatly determined by the synergistic presence of substitutions. Within the range tested, fluctuations of Nod factor amounts had little impact on the symbiotic phenotype.     

Production and Excretion of Nod Metabolites by Rhizobium leguminosarum bv. trifolii Are Disrupted by the Same Environmental Factors That Reduce Nodulation in the Field

Lipooligosaccharides (Nod metabolites) have been shown to be essential for the successful nodulation of legumes. In strains of Rhizobium leguminosarum bv. trifolii, Nod metabolites were detected predominantly within the cell and to a lesser extent in the periplasmic space and the growth medium. The production, and in particular the excretion, of Nod metabolites was restricted by a range of environmental conditions which are associated with poor nodulation in the field. Lowering the medium pH from 7.0 to 5.0, reducing the phosphate concentration from 1 mM to 5 μM KH₂PO₄, and lowering the incubation temperature from 28 to 18°C affected the number and relative concentrations of the Nod metabolites made. The form and concentration of the nitrogen source affected the relative concentrations of the Nod metabolites produced and excreted. KNO₃ concentrations of >10 mM did not affect cell growth rate but substantially reduced the number of Nod metabolites released. Environmental stresses differentially altered Nod metabolite production and excretion in the same strain carrying different introduced nod regions. Strain ANU845(pWLH1) produced and excreted comparatively fewer Nod metabolites at pH 5.0 and at 18°C than strain ANU845(pRI4003). The excretion but not the production of Nod metabolites by strain ANU845(pRtO32) was dependent on the presence of both nodI and nodJ. Tn5-induced nodI and nodJ mutants did not accumulate any metabolites either outside the cell or within the outer membrane or periplasmic space. Recognition that Nod metabolite accumulation is a complex system of production and excretion, with each component responding differently to changes in environmental conditions, has many consequences, both at the molecular level and in the field. The ability of different strains to produce and release Nod metabolites is likely to be a major determinant of nodule occupancy and should be considered when screening strains suitable for adverse environments.     

Nodulation of specific legumes is controlled by several distinct loci in Rhizobium trifolii

Summary Three distinct loci (designated regions III, IV and V) were identified in the 14 kb Nod region of Rhizobium trifolii strain ANU843 and were found to determine the host range characteristics of this strain. Deletion of region III or region V only from the 14 kb Nod region affected clover nodulation capacity. The introduction to R. Leguminosarum of DNA fragments on multicopy vectors carrying regions III, IV and V (but not smaller fragments) extended the host range of R. leguminosarum so that infection threads and nodules occurred on white clover plants. The same DNA fragments were introduced to the Sym plasmid-cured strain (ANU845) carrying the R. meliloti recombinant nodulation plasmid pRmSL26. Plasmid pRmSL26 alone does not confer root hair curling or nodulation on clover plants. However, the introduction to ANU845 (pRmSL26) of a 1.4 kb fragment carrying R. trifolii region IV only, resulted in the phenotypic activation of marked root hair curling ability to this strain on clovers but no infection events or nodules resulted. Only the transfer of regions III, IV and V to strain ANU845 (pRmSL26) conferred normal nodulation and host range ability of the original wild type R. trifolii strain. These results indicate that the host range genes determine the outcome of early plant-bacterial interactions primarily at the stage of root hair curling and infection.     

Genetic and functional analysis of the nodulation region of the Rhizobium leguminosarum Sym plasmid pRL1JI

Thirty Tn5- or Tn1831-induced nodulation (nod) mutants of Rhizobium leguminosarum were examined for their genetic and symbiotic properties. Thirteen mutants contained a deletion in Sym plasmid pRL1JI. These deletions cover the whole nod region and are 50 kb in size. All remaining seventeen mutations are located in a 6.6 kb EcoRI nod fragment of the Sym plasmid. Mutations in a 3.5 kb part on the right hand side of this 6.6 kb fragment completely prevent nodulation on Vicia sativa. All mutants in this 3.5 kb area are unable to induce marked root hair curling and thick and short roots.Mutations in a 1.5 kb area on the left hand side of the 6.6 kb nod fragment generate other symbiotic defects in that nodules are only rarely formed and only so after a delay of several days. Moreover, infection thread formation is delayed and root hair curling is more excessive than that caused by the parental strain. Their ability to induce thick and short roots is unaltered.Mutations in this 1.5 kb region are not complemented by pRmSL26, which carries nod genes of R. meliloti, whereas mutations in the 3.5 kb region are all complemented by pRmSL26.Abbreviations Rps repression of production of small bacteriocin - Mep medium bacteriocin production - Nod nodulation - Fix fixation - Tsr thick and short roots - Flac root hair curling - Hsp host specificity - Flad root hair deformation - Tc tetracycline - Km kanamycin - Cm chloramphenicol - Sp spectinomycin - Sm streptomycin - R resistant     

NolL of Rhizobium sp. Strain NGR234 Is Required for O-Acetyltransferase Activity

Following (iso)flavonoid induction, nodulation genes of the symbiotic nitrogen-fixing bacterium Rhizobium sp. strain NGR234 elaborate a large family of lipooligosaccharidic Nod factors (NodNGR factors). When secreted into the rhizosphere of compatible legumes, these signal molecules initiate root hair deformation and nodule development. The nonreducing glucosamine residue of NodNGR factors are N acylated, N methylated, and mono- or biscarbamoylated, while position C-6 of the reducing extremity is fucosylated. This fucose residue is normally 2-O methylated and either sulfated or acetylated. Here we present an analysis of all acetylated NodNGR factors, which clearly shows that the acetate group may occupy position C-3 or C-4 of the fucose moiety. Disruption of the flavonoid-inducible nolL gene, which is preceded by a nod box, results in the synthesis of NodNGR factors that lack the 3-O- or 4-O-acetate groups. Interestingly, the nodulation capacity of the mutant NGRΩnolL is not impaired, whereas introduction of the nod box::nolL construct into the related strain Rhizobium fredii USDA257 extends the host range of this bacterium to Calopogonium caeruleum, Leucaena leucocephala, and Lotus halophilus. Nod factors produced by a USDA257(pnolL) transconjugant were also acetylated. The nod box::nolL construct was also introduced into ANU265 (NGR234 cured of its symbiotic plasmid), along with extra copies of the nodD1 gene. When permeabilized, these cells possessed acetyltransferase activity, although crude extracts did not.     

Rhizobial lipo-oligosaccharide nodulation factors: multidimensional chromatographic analysis of symbiotic signals involved in the development of legume root nodules

Nod factors are a group of biologically active oligosaccharidesignals that are secreted by symbiotically competent bacteriaof the family Rhizobiaceae. Their biosynthesis is determinedby rhizobial nodulation (nod) genes, and is specifically inducedin response to flavonoids secreted from the roots of host leguminousplants. The biological activity of Nod factors on these hostlegumes dramatically mimics the early developmental symptomsof the Rhizobium-legame symbiosis including, amongst other effects,root hair deformations and nodule initiation. Structurally,all Nod factors are short oligomers of ß-1,4-linkedN-acetylglucos-amine residues [usually degree of polymerization(dp) 4 or 5] that are N-acylated on the distal glucosarnine.This common ‘core’ structure may be modified bya number of species-specific substituents on the distal or reducingsugars. These modifications are governed by rhizobial host specificitynod genes. The biological activity of purified Nod factors mirrorsthis host specificity, indicating that the symbiotic host rangeof individual Rhizobium species is, at least partially, determinedby the variety of Nod factors they are able to produce. Herewe describe techniques that are universally applicable to theextraction, chromatographic separation and identification ofNod factors. We have applied these techniques to Nod factorsfrom the broad-host-range species Rhizobium fredii USDA257 andRhizobium spp. NGR234, and the more narrow-host-range Bradyrhizobiumjaponicum USDA110, and have identified a group of novel, relativelyhydrophilic Nod factors from the NGR234 species that may haveimplications for Nod factor biosynthesis. lipo-oligosaccharide Nod factor rhibozobia singals TLC     

NopC Is a Rhizobium-Specific Type 3 Secretion System Effector Secreted by Sinorhizobium (Ensifer) fredii HH103

Sinorhizobium (Ensifer) fredii HH103 is a broad host-range nitrogen-fixing bacterium able to nodulate many legumes, including soybean. In several rhizobia, root nodulation is influenced by proteins secreted through the type 3 secretion system (T3SS). This specialized secretion apparatus is a common virulence mechanism of many plant and animal pathogenic bacteria that delivers proteins, called effectors, directly into the eukaryotic host cells where they interfere with signal transduction pathways and promote infection by suppressing host defenses. In rhizobia, secreted proteins, called nodulation outer proteins (Nops), are involved in host-range determination and symbiotic efficiency. S. fredii HH103 secretes at least eight Nops through the T3SS. Interestingly, there are Rhizobium-specific Nops, such as NopC, which do not have homologues in pathogenic bacteria. In this work we studied the S. fredii HH103 nopC gene and confirmed that its expression was regulated in a flavonoid-, NodD1- and TtsI-dependent manner. Besides, in vivo bioluminescent studies indicated that the S. fredii HH103 T3SS was expressed in young soybean nodules and adenylate cyclase assays confirmed that NopC was delivered directly into soybean root cells by means of the T3SS machinery. Finally, nodulation assays showed that NopC exerted a positive effect on symbiosis with Glycine max cv. Williams 82 and Vigna unguiculata. All these results indicate that NopC can be considered a Rhizobium-specific effector secreted by S. fredii HH103.     

Mutants of Serratia marcescens lacking cyclic nucleotide phosphodiesterase activity and requiring cyclic 3′,5′-AMP for the utilization of various carbohydrates

Adenine requiring mutants of Serratia marcescens SM-6-F'lac ⁺ have been found to grow well in minimal-glucose medium solely supplemented with cAMP. From one of these ade strains double mutants (called ade cpd) were isolated which could no longer utilize cAMP but which still grew on 5′AMP. Dialyzed cell extracts (soluble fraction) of the double mutants, assayed for cAMP phosphodiesterase, were unable to hydrolyze cAMP whereas cell extracts of the parental strains yielded 5′AMP at a rate of 1.6–2.0 μmoles min⁻¹ mg⁻¹ protein. The loss of the phosphodiesterase activity in S. marcescens cpd W1181 did not cause an accumulation of large amounts of cAMP as was found for the diesterase-negative mutant AB257^pc-1 of Escherichia coli. The induced synthesis of β-galactosidase in mutant cpd W 1181 showed about the same sensitivity to transient and permanent catabolite (glucose) repression as the corresponding cpd ⁺ strain. Starting from S. marcescens cpd W1181 three independent double mutants (called cpd cya) were isolated which required exogenous cAMP for utilizing various carbohydrates as carbon source, for motility and for the formation of extracellular lipase and the red pigment prodigiosine. The intracellular concentration of cAMP in these mutants, grown in nutrient broth, was 40–60% of that of the parental strain which is about 4×10⁻⁴ M. However, the adenylate cyclase in cell extracts of the mutants W1237 and W1270 was like that of the corresponding cya ⁺ strain (about 2×10⁻² μmoles min⁻¹ mg⁻¹ protein).     

Rearrangement of Actin Microfilaments in Plant Root Hairs Responding to Rhizobium etli Nodulation Signals

The response of the actin cytoskeleton to nodulation (Nod) factors secreted by Rhizobium etli has been studied in living root hairs of bean (Phaseolus vulgaris) that were microinjected with fluorescein isothiocyanate-phalloidin. In untreated control cells or cells treated with the inactive chitin oligomer, the actin cytoskeleton was organized into long bundles that were oriented parallel to the long axis of the root hair and extended into the apical zone. Upon exposure to R. etli Nod factors, the filamentous actin became fragmented, as indicated by the appearance of prominent masses of diffuse fluorescence in the apical region of the root hair. These changes in the actin cytoskeleton were rapid, observed as soon as 5 to 10 min after application of the Nod factors. It was interesting that the filamentous actin partially recovered in the continued presence of the Nod factor: by 1 h, long bundles had reformed. However, these cells still contained a significant amount of diffuse fluorescence in the apical zone and in the nuclear area, presumably indicating the presence of short actin filaments. These results indicate that Nod factors alter the organization of actin microfilaments in root hair cells, and this could be a prelude for the formation of infection threads.     

Effect of Sym Plasmid Curing on Symbiotic Effectiveness in Rhizobium fredii

A mutant, USDA 206C, of Rhizobium fredii USDA 206 was obtained by passage on acridine plates. This mutant was cured of its 197-megadalton Sym plasmid but retained its symbiotic effectiveness. Multiple plasmid and chromosomally borne nif gene copies have previously been shown in R. fredii USDA 206. HindIII and EcoRI restriction enzyme digests of plasmid and total DNA showed that at least two nif gene copies are probably missing in USDA 206C. To compare the symbiotic effectiveness of USDA 206 and USDA 206C, plant tests were carried out. Statistically significant differences were obtained for nodule number, nodule mass, nitrogenase activity per plant, nitrogenase specific activity, and total plant dry weight. There was an apparent correlation between loss of Sym plasmidborne nif gene copies and reduction of overall symbiotic effectiveness. Delayed nodulation by strain USDA 206C relative to strain USDA 206 also indicated an association with the loss of plasmidborne nodulation functions and the reduced symbiotic effectiveness of strain USDA 206C.     

Two rhizobacterial strains,individually and in interactions with Rhizobium sp., enhance fusarial wilt control,growth, and yield in pigeon pea

A Pseudomonas aeruginosa strain, RRLJ 04, and a Bacillus cereus strain, BS 03, were tested both individually and in combination with a Rhizobium strain, RH 2, for their ability to enhance plant growth and nodulation in pigeon pea (Cajanus cajan L.) under gnotobiotic, greenhouse and field conditions. Both of the rhizobacterial strains exhibited a positive effect on growth in terms of shoot height, root length, fresh and dry weight, nodulation and yield over the non-treated control. Co-inoculation of seeds with these strains and Rhizobium RH 2 also reduced the number of wilted plants, when grown in soil infested with Fusarium udum. Gnotobiotic studies confirmed that the suppression of wilt disease was due to the presence of the respective PGPR strains. Seed bacterization with drug-marked mutants of RRLJ 04 and BS 03 confirmed their ability to colonize and multiply along the roots. The results suggest that co-inoculation of these strains with Rhizobium strain RH 2 can be further exploited for enhanced growth, nodulation and yield in addition to control of fusarial wilt in pigeon pea.     

Burkholderia sp. Induces Functional Nodules on the South African Invasive Legume Dipogon lignosus (Phaseoleae) in New Zealand Soils

The South African invasive legume Dipogon lignosus (Phaseoleae) produces nodules with both determinate and indeterminate characteristics in New Zealand (NZ) soils. Ten bacterial isolates produced functional nodules on D. lignosus. The 16S ribosomal RNA (rRNA) gene sequences identified one isolate as Bradyrhizobium sp., one isolate as Rhizobium sp. and eight isolates as Burkholderia sp. The Bradyrhizobium sp. and Rhizobium sp. 16S rRNA sequences were identical to those of strains previously isolated from crop plants and may have originated from inocula used on crops. Both 16S rRNA and DNA recombinase A (recA) gene sequences placed the eight Burkholderia isolates separate from previously described Burkholderia rhizobial species. However, the isolates showed a very close relationship to Burkholderia rhizobial strains isolated from South African plants with respect to their nitrogenase iron protein (nifH), N-acyltransferase nodulation protein A (nodA) and N-acetylglucosaminyl transferase nodulation protein C (nodC) gene sequences. Gene sequences and enterobacterial repetitive intergenic consensus (ERIC) PCR and repetitive element palindromic PCR (rep-PCR) banding patterns indicated that the eight Burkholderia isolates separated into five clones of one strain and three of another. One strain was tested and shown to produce functional nodules on a range of South African plants previously reported to be nodulated by Burkholderia tuberum STM678^T which was isolated from the Cape Region. Thus, evidence is strong that the Burkholderia strains isolated here originated in South Africa and were somehow transported with the plants from their native habitat to NZ. It is possible that the strains are of a new species capable of nodulating legumes.     

Trifolitoxin Production and Nodulation Are Necessary for the Expression of Superior Nodulation Competitiveness by Rhizobium leguminosarum bv. trifolii Strain T24 on Clover

Rhizobium leguminosarum bv. trifolii T24 is ineffective in symbiotic nitrogen fixation, produces a potent antibiotic (referred to here as trifolitoxin) that is bacteriostatic to certain Rhizobium strains, and is very competitive for clover root nodulation (EA Schwinghamer, RP Belkengren 1968 Arch Mikrobiol 64: 130-145). The primary objective of this work was to demonstrate the roles of nodulation and trifolitoxin production in the expression of nodulation competitiveness by T24. Unlike wildtype T24, transposon mutants of T24 lacking trifolitoxin production were unable to decrease clover nodulation by an effective, trifolitoxin-sensitive strain of R. leguminosarum bv. trifolii. A non-nodulating transposon mutant of T24 prevented clover nodulation by a trifolitoxin-sensitive R. leguminosarum bv. trifolii when co-inoculated with a T24 mutant lacking trifolitoxin production. Neither mutant alone prevented nodulation by the trifolitoxin-sensitive strain. These results demonstrate that trifolitoxin production and nodulation are required for the expression of nodulation competitiveness by strain T24. A trifolitoxin-sensitive strain of R. meliloti did not nodulate alfalfa when co-inoculated with T24 and a trifolitoxin-resistant strain of R. meliloti. Thus, a trifolitoxin-producing strain was useful in regulating nodule occupancy on a legume host other than clover. Trifolitoxin production was constitutive in both minimal and enriched media. Trifolitoxin was found to inhibit the growth of 95% of all strains of R. leguminosarum bvs. trifolii, viceae, and phaseoli tested. Strains of all 13 biotypes of R. leguminosarum bv. trifolii were inhibited by trifolitoxin. Three strains of R. fredii were also inhibited. Strain T24 ineffectively nodulated 46 clover species, did not nodulate Trifolium ambiguum, and induced partially effective nodules on Trifolium micranthum. Since T24 produced partially effective nodules on T. micranthum and since a trifolitoxin-minus mutant of T24 induced ineffective nodules, trifolitoxin production is not the cause of the symbiotic ineffectiveness of T24.     

Microbial strain improvement for enhanced polygalacturonase production by Aspergillus sojae

Strain improvement is a powerful tool in commercial development of microbial fermentation processes. Strains of Aspergillus sojae which were previously identified as polygalacturonase producers were subjected to the cost-effective mutagenesis and selection method, the so-called random screening. Physical (ultraviolet irradiation at 254 nm) and chemical mutagens (N-methyl-N′-nitro-N-nitrosoguanidine) were used in the development and implementation of a classical mutation and selection strategy for the improved production of pectic acid-degrading enzymes. Three mutation cycles of both mutagenic treatments and also the combination of them were performed to generate mutants descending from A. sojae ATCC 20235 and mutants of A. sojae CBS 100928. Pectinolytic enzyme production of the mutants was compared to their wild types in submerged and solid-state fermentation. Comparing both strains, higher pectinase activity was obtained by A. sojae ATCC 20235 and mutants thereof. The highest polygalacturonase activity (1,087.2?±?151.9 U/g) in solid-state culture was obtained by mutant M3, which was 1.7 times increased in comparison to the wild strain, A. sojae ATCC 20235. Additional, further mutation of mutant M3 for two more cycles of treatment by UV irradiation generated mutant DH56 with the highest polygalacturonase activity (98.8?±?8.7 U/mL) in submerged culture. This corresponded to 2.4-fold enhanced polygalacturonase production in comparison to the wild strain. The results of this study indicated the development of a classical mutation and selection strategy as a promising tool to improve pectinolytic enzyme production by both fungal strains.