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Applied Microbiology and Biotechnology (v.54, #4)
Engineering bacterial biopolymers for the biosorption of heavy metals; new products and novel formulations by D. L. Gutnick; H. Bach (pp. 451-460).
Bioremediation of heavy metal pollution remains a major challenge in environmental biotechnology. One of the approaches considered for application involves biosorption either to biomass or to isolated biopolymers. Many bacterial polysaccharides have been shown to bind heavy metals with varying degrees of specificity and affinity. While various approaches have been adopted to generate polysaccharide variants altered in both structure and activity, metal biosorption has not been examined. Polymer engineering has included structural modification through the introduction of heterologous genes of the biosynthetic pathway into specific mutants, leading either to alterations in polysaccharide backbone or side chains, or to sugar modification. In addition, novel formulations can be designed which enlarge the family of available bacterial biopolymers for metal-binding and subsequent recovery. An example discussed here is the use of amphipathic bioemulsifiers such as emulsan, produced by the oil-degrading Acinetobacter lwoffii RAG-1, that forms stable, concentrated (70%), oil-in-water emulsions (emulsanosols). In this system metal ions bind primarily at the oil/water interface, enabling their recovery and concentration from relatively dilute solutions. In addition to the genetic modifications described above, a new approach to the generation of amphipathic bioemulsifying formulations is based on the interaction of native or recombinant esterase and its derivatives with emulsan and other water-soluble biopolymers. Cation-binding emulsions are generated from a variety of hydrophobic substrates. The features of these and other systems will be discussed, together with a brief consideration of possible applications.
Biodegradation of nylon oligomers by S. Negoro (pp. 461-466).
This mini-review is a compendium of the degradation of a man-made compound, 6-aminohexanoate-oligomer, in Flavobacterium strains. The results are summarized as follows:1. Three enzymes, 6-aminohexanoate-cyclic-dimer hydrolase (EI), 6-aminohexanoate-dimer hydrolase (EII), and endotype 6-aminohexanoate-oligomer hydrolase (EIII) were responsible for degradation of the oligomers.2. The genes coding these enzymes were located on pOAD2, one of three plasmids harbored in Flavobacterium sp. KI72, which comprised 45,519 bp.3. The gene coding the EII′ protein (a protein having 88% homology with EII) and five IS6100 elements were identified on pOAD2.4. The specific activity of EII was 200-fold higher than that of EII′. However, altering two amino acid residues in the EII′ enzyme enhanced the activity of EII′ to the same level as that of the EII enzyme.5. The deduced amino acid sequences from eight regions of pOAD2 had significant similarity with the sequences of gene products such as oppA-F (encoding oligopeptide permease), ftsX (filamentation temperature sensitivity), penDE (isopenicillin N-acyltransferase) and rep (plasmid replication).6. The EI and EII genes of Pseudomonas sp. NK87 (another nylon oligomer-degrading bacterium) were also located on plasmids.7. Through selective cultivation using nylon oligomers as a sole source of carbon and nitrogen, two strains which initially had no metabolic activity for nylon oligomers, Flavobacterium sp. KI725 and Pseudomonas aeruginosa PAO1, were given the ability to degrade xenobiotic compounds. A molecular basis for the adaptation of microorganisms toward xenobiotic compounds was described.
Clavulanic acid, a β-lactamase inhibitor: biosynthesis and molecular genetics by P. Liras; A. Rodríguez-García (pp. 467-475).
Clavulanic acid is a secondary metabolite produced by Streptomyces clavuligerus. It possesses a clavam structure and a characteristic 3R,5R stereochemistry essential for action as a β-lactamase inhibitory molecule. It is produced from glyceraldehyde-3-phosphate and arginine in an eight step biosynthetic pathway. The pathway is carried out by unusual enzymes, such as (1) the enzyme condensing both precursors, N 2-(2-carboxyethyl)-arginine (CEA) synthetase, (2) the β-lactam synthetase cyclizing CEA and (3) the clavaminate synthetase, a well-characterized multifunctional enzyme. Genes for biosynthesis of clavulanic acid and other clavams have been cloned and characterized. They offer new possibilities for modification of the pathway and for obtaining new molecules with a clavam structure. The state of the regulatory proteins controlling clavulanic acid biosynthesis, as well as the relationship between the biosynthetic pathway of clavulanic acid and other clavams, is discussed.
Aqueous two-phase: the system of choice for extractive fermentation by J. Sinha; P. K. Dey; T. Panda (pp. 476-486).
Extractive fermentation in aqueous two-phase systems is a meaningful approach to overcome low product yield in a conventional fermentation process, and by proper design of the two-phase system it is possible to obtain the product in a cell-free stream. The characteristics of an aqueous two-phase system, various polymers used for forming an aqueous two-phase system, the physicochemical parameters of the aqueous two-phase system, partitioning of biomolecules and cell mass and the effect of individual phase forming polymers on cell growth and product formation are reviewed in this article. The various extractive fermentation processes are also summarised here. At the end, the economic viability and scope of aqueous two-phase fermentation are briefly discussed in relation to the wider application of this topic.
Effect of feeding strategy on Zymomonas mobilis CP4 fed-batch fermentations and mathematical modeling of the system by S. Bravo; A. Mahn; C. Shene (pp. 487-493).
In this work, the effect of the feeding strategy in Zymomonas mobilis CP4 fed-batch fermentations on the final biomass and ethanol concentrations was studied. Highest glucose yields to biomass (0.018 g/g) and to ethanol (0.188 g/g) were obtained in fed-batch fermentations carried out using different feeding rates with a glucose concentration in the feed equal to 100 g/l. Lower values (0.0102 g biomass/g glucose and 0.085 g ethanol/g glucose) were obtained when glucose accumulated to levels higher than 60 g/l. On the other hand, the highest biomass (5 g/l) and ethanol (39 g/l) concentrations were obtained using a glucose concentration in the feed equal to 220 g/l and exponentially varied feeding rates. Experimental data were used to validate the mathematical model of the system. The prediction errors of the model are 0.39, 14.36 and 3.24 g/l for the biomass, glucose and ethanol concentrations, respectively. Due to the complex relationship for describing the specific growth rate, a fed-batch culture in which glucose concentration is constant would not optimize the process.
Anaerobic bioconversion of cellulose by Ruminococcus albus, Methanobrevibacter smithii, and Methanosarcina barkeri by T. L. Miller; E. Currenti; M. J. Wolin (pp. 494-498).
A system is described that combines the fermentation of cellulose to acetate, CH4, and CO2 by Ruminococcus albus and Methanobrevibacter smithii with the fermentation of acetate to CH4 and CO2 by Methanosarcina barkeri to convert cellulose to CH4 and CO2. A cellulose-containing medium was pumped into a co-culture of the cellulolytic R. albus and the H2-using methanogen, Mb. smithii. The effluent was fed into a holding reservoir, adjusted to pH 4.5, and then pumped into a culture of Ms. barkeri maintained at constant volume by pumping out culture contents. Fermentation of 1% cellulose to CH4 and CO2 was accomplished during 132 days of operation with retention times (RTs) of the Ms. barkeri culture of 7.5–3.8 days. Rates of acetate utilization were 9.5–17.3 mmol l−1 day−1 and increased with decreasing RT. The K s for acetate utilization was 6–8 mM. The two-stage system can be used as a model system for studying biological and physical parameters that influence the bioconversion process. Our results suggest that manipulating the different phases of cellulose fermentation separately can effectively balance the pH and ionic requirements of the acid-producing phase with the acid-using phase of the overall fermentation.
Cloning, sequencing, and functional analysis of H-OLE1 gene encoding Δ9-fatty acid desaturase in Hansenula polymorpha by S.-F. Lu; I. I. Tolstorukov; S. Anamnart; Y. Kaneko; S. Harashima (pp. 499-509).
H-OLE1, a gene encoding Δ9-fatty acid desaturase (FAD) in Hansenula polymorpha strain CBS 1976, was isolated by hybridization based upon its homology with the P-OLE1 gene cloned earlier from a related species, Pichia angusta IFO 1475. The sequence of the H-OLE1 gene revealed high structural conservation with Δ9-FADs from various organisms. A putative 451-amino acid polypeptide encoded by the gene, like all other Δ9-FADs, contained two domains: an N-terminal catalytic domain containing three conserved histidine clusters, and a C-terminal cytochrome b 5-like domain which has been suggested to be involved in electron transport in desaturation reactions. The whole H-OLE1 gene complemented a H. polymorpha fad1 mutation leading to a defect in Δ9-FAD. However, the unsaturated fatty acid requirement that the Saccharomyces cerevisiae ole1 mutant displays was complemented by only the open reading frame of H-OLE1 driven by S. cerevisiae glyceroaldehyde-3-phosphate dehydrogenase promoter, but not by the intact H-OLE1, suggesting that the H. polymorphaΔ9-FAD was compatible with the desaturation system of S. cerevisiae whereas the promoter of the H-OLE1 gene had no activity in heterologous cells. It was shown by Northern hybridization that transcription of the H-OLE1 gene in H. polymorpha was slightly repressed by exogenous Δ9-unsaturated fatty acid. An H. polymorpha disruption mutant (ΔH-OLE1) was created by transformation of an fad1/FAD1 diploid with disrupted H-OLE1::S-LEU2 linear DNA. It was shown by genetic and molecular analyses that input DNA was integrated in several copies into the chromosomal target to replace the mutated fad1 allele. Gas chromatography analysis showed identical fatty acid compositions in cells of both fad1 and ΔHOLE1 disruption mutants.
Enhanced stability of laccase in the presence of phenolic compounds by C. Mai; W. Schormann; O. Milstein; A. Hüttermann (pp. 510-514).
The storage stability of laccase (EC 1.10.3.2) from the white-rot basidomycete Trametes versicolor in potassium-citrate buffer was enhanced by various phenolic compounds as well as by lignin sulfonate. The highest storage stability was obtained with phenolics, e.g. phloroglucin and 3,5-dihydroxybenzoic acid; these represent substrates of laccase which are oxidized slowly because of their relatively high redox potential and which did not precipitate from the solution within the tested period of time. Sterilization enhanced the stability of laccase but additional stabilization by phenolics was observed both under sterile and non-sterile conditions. We thus concluded that stabilization occurred not only through prevention of microbial degradation.
Application of the response surface methodology for optimizing the activity of an aprE-driven gene expression system in Bacillus subtilis by E. R. El-Helow; Y. R. Abdel-Fattah; K. M. Ghanem; E. A. Mohamad (pp. 515-520).
The major targets for improvement of recombinant expression systems in microbial cells are gene dosage, transcriptional control machinery and, to some extent, translation. Here we show that optimization of fermentation conditions by applying statistically designed, multifactorial experiments offers an additional method for potential enhancement of gene expression systems. A chromosomally encoded fusion between the Bacillus subtilis aprE regulatory region and the E. coli lacZ gene carried by the B. subtilis host cells was used. The 2 × SG sporulation medium was used as a basal medium. Among the 11 fermentation factors we examined, the most significant variables influencing β-galactosidase expression were statistically elucidated for optimization and included peptone, MgSO4 · 7H2O, and KCl. The optimum concentrations of these variables were predicted by using a second-order polynomial model fitted to the results obtained by applying the Box-Behnken design, a response surface method. Calculated optimum concentrations were predicted to confer a maximum yield of 2,423.5 β-galactosidase specific activity units. A verification experiment performed under optimal conditions yielded 96% of the predicted specific activity value with an increase by a factor of almost 5 compared with the results obtained under basal conditions.
Molecular characterization of xynX, a gene encoding a multidomain xylanase with a thermostabilizing domain from Clostridium thermocellum by H. Kim; K. H. Jung; M. Y. Pack (pp. 521-527).
A Clostridium thermocellum gene, xynX, coding for a xylanase was cloned and the complete nucleotide sequence was determined. The xylanase gene of Clostridium thermocellum consists of an ORF of 3261 nucleotide encoding a xylanase (XynX) of 1087 amino acid residues (116 kDa). Sequence analysis of XynX showed a multidomain structure that consisted of four different domains: an N-terminal thermostabilizing domain homologous to sequences found in several thermophilic enzymes, a catalytic domain homologous to family 10 glycosyl hydrolases, a duplicated cellulose-binding domain (CBD) homologous to family IX CBDs, and a triplicated S-layer homologous domain. A deletion mutant of xynX having only the catalytic region produced a mutant enzyme XynX-C which retained catalytic activity but lost thermostability. In terms of half-life at 70 °C, the thermostability of XynX-C was about six times lower than that of the other mutant enzyme, XynX-TC, produced by a mutant containing both the thermostabilizing domain and the catalytic domain. The optimum temperature of XynX-C was about 5–10 °C lower than that of XynX-TC.
Bioconversion of lutein to products with aroma by A. Sánchez-Contreras; M. Jiménez; S. Sanchez (pp. 528-534).
A residual mud sample from the marigold flower dehydration process was screened and 19 putative colonies were isolated for their ability to degrade lutein in a chemically defined medium supplemented with marigold flower flour as a carbon source. Among the colonies isolated, two generated volatile compounds in fermentation and one was chosen for further study for its ability to produce a strong tobacco smell. This colony contained two microorganisms, identified as Geotrichum sp. and Bacillus sp. The aroma production requires the presence of both microorganisms and lutein. Using gas chromatography coupled to mass spectrometry (GC/MS), four compounds were identified: 7,8-dihydro- β-ionol, β-ionone, 7,8-dihydro-β-ionone, and 3-hydroxy-β-ionone, in proportions of 84.2%, 9.4%, 3.5%, and 2.9%, respectively.
Effect of dissolved oxygen and carbon–nitrogen loads on denitrification by an aerobic consortium by D. Patureau; N. Bernet; J. P. Delgenès; R. Moletta (pp. 535-542).
Four samples of natural ecosystems and one sample from an activated sludge treatment plant were mixed together and progressively adapted to alternating aerobic/anoxic phases in the presence of nitrate in order to enrich the microflora in aerobic denitrifiers. Aerobic denitrifying performances of this mixed ecosystem at various dissolved oxygen concentrations and various carbon–nitrogen loads were evaluated and compared to those obtained with the aerobic denitrifier Microvirgula aerodenitrificans. The consortium and the pure strain exhibited an aerobic denitrifying activity at air saturation conditions (7 mg dissolved oxygen l–1), i.e. there was co-respiration of the two electron acceptors with significant specific nitrate reduction rates. Dissolved oxygen concentrations had no influence on denitrifying performances above a defined threshold: 0.35 mg l–1 for the consortium and 4.5 mg l–1 for M. aerodenitrificans respectively. Under these thresholds, decreasing the dissolved oxygen concentrations enhanced the denitrifying activity of each culture. The higher the carbon and nitrogen loads, the higher the performance of the aerobic denitrifying ecosystem. However, for M. aerodenitrificans, the nitrate reduction percentage was affected more by variations in nitrogen load than in carbon load.
Inhibition of the development of microorganisms (bacteria and fungi) by extracts of marine algae from Brittany, France by C. Hellio; G. Bremer; A. M. Pons; Y. Le Gal; N. Bourgougnon (pp. 543-549).
The inhibitory effects of aqueous, ethanolic and dichloromethane fractions from 16 marine algae from the Atlantic shores of North-East Brittany, France, have been investigated against microorganisms frequently associated with immersed surfaces. The extracts were tested in vitro against isolates of marine fungi, bacteria and yeasts potentially involved at different stages in the formation of biofilms in the sea. The high levels of inhibitory activity of nine extracts against marine fungi and Gram-positive bacteria and their apparent absence of toxicity against larvae of oysters and sea urchins suggests a potential for novel active ingredients.
In vivo antioxidant role of astaxanthin under oxidative stress in the green alga Haematococcus pluvialis by M. Kobayashi (pp. 550-555).
Intracellular production of active oxygen in the green alga Haematococcus pluvialis was studied by measuring the capacity for in vivo conversion of 2′,7′-dichlorohydrofluorescein diacetate to the fluorescent dye dichlorofluorescein in different algal cell types (i.e., vegetative, immature cyst and mature cyst cells). The increase in formation of dichlorofluorescein by methyl viologen (superoxide anion radical generator) was linear for 2 h in immature cyst cells (low astaxanthin) in a methyl viologen-concentration-dependent manner, while no production was detected in mature (high astaxanthin) cysts. Compared to cyst cells, formation of dichlorofluorescein in vegetative cells (no astaxanthin) was markedly increased by methyl viologen. The formation of dichlorofluorescein in cyst cells was decreased with higher astaxanthin content under excessive oxidative stress. All of the active oxygen species tested (singlet oxygen, superoxide anion radical, hydrogen peroxide and peroxy radical) at 10−3 M increased the intracellular dichlorofluorescein formation in immature cysts, but did not increase the dichlorofluorescein content of mature cysts. Therefore, astaxanthin in cyst cells appeared to function as an antioxidant agent against oxidative stress.
Loss of glucose repression in an Acremonium chrysogenumβ-lactam producer strain and its restoration by multiple copies of the cre1 gene by K. Jekosch; U. Kück (pp. 556-563).
In the filamentous fungus Acremonium chrysogenum, biosynthesis of the β-lactam antibiotic cephalosporin C is repressed by glucose. A wild-type strain grown in the presence of glucose shows a reduction of transcripts derived from the pcbC and cefEF biosynthesis genes. Interestingly, the amount of the pcbC transcript is not affected in another strain with enhanced cephalosporin C production, suggesting a correlation between strain improvement and deregulation of glucose repression. The function of the glucose repressor CRE1 in this regulation was further analyzed by transforming both A. chrysogenum strains with multiple copies of the cre1 gene. The molecular analysis of transformants revealed that additional copies of the cre1 gene restore wild-type-like regulation of pcbC gene expression in the semiproducer strain, while repression of the cefEF gene expression is increased. Overall, our data indicate a regulation of the pcbC and the cefEF gene expression by CRE1.
The carbon source influences the energetic efficiency of the respiratory chain of N2-fixing Acetobacter diazotrophicus by M. F. Luna; C. F. Mignone; J. L. Boiardi (pp. 564-569).
Acetobacter diazotrophicus is a diazotrophic bacterium that colonizes sugarcane tissues. Glucose is oxidized to gluconate in the periplasm prior to uptake and metabolism. A membrane-bound glucose dehydrogenase quinoenzyme [which contains pyrroloquinoline quinone (PQQ) as the prosthetic group] is involved in that oxidation. Gluconate is oxidized further via the hexose monophosphate pathway and tricarboxylic acid cycle. A. diazotrophicus PAL3 was grown in a chemostat with atmospheric nitrogen as the sole N source provided that the dissolved oxygen was maintained at 1.0–2.0% air saturation. The biomass yields of A. diazotrophicus growing with glucose or gluconate with fixed N were very low compared with other heterotrophic bacteria. The biomass yields under N-fixing conditions were more than 30% less than with ammonium as the N source using gluconate as the carbon source but, surprisingly, were only about 14% less with glucose. The following scheme for the metabolism of A. diazotrophicus through the different pathways emerged: (1) the respiratory chain of this organism had a different efficiency of ATP production in the respiratory chain (P:O ratio) under different culture conditions; and (2) N fixation was one (but not the sole) condition under which a higher P:O ratio was observed. The other condition appears to be the expression of an active PQQ-linked glucose dehydrogenase.
Fibrobacter succinogenes S85 ferments ball-milled cellulose as fast as cellobiose until cellulose surface area is limiting by M. W. Fields; S. Mallik; J. B. Russell (pp. 570-574).
Fibrobacter succinogenes S85 grew rapidly on cellobiose (0.31 h−1) and the absolute rate of increase in fermentation acids was 0.68 h−1. Cultures that were provided with ball-milled cellulose initially produced fermentation acids and microbial protein as fast as those provided with cellobiose, but the absolute cellulose digestion rate eventually declined. If the inoculum size was increased, the kinetics decayed from first to zero order (with respect to cells) even sooner, but in each case the absolute rate declined after only 20 to 30% of the cellulose had been fermented. Congo red binding indicated that the cellulose surface area of individual cellulose particles was not decreasing, and the transition of ball-milled cellulose digestion corresponded with the appearance of unbound cells in the culture supernatant. When bound cells from partially digested cellulose were removed and the cellulose was re-incubated with a fresh inoculum, the initial absolute fermentation rate was as high as the one observed for undigested cellulose and cellobiose. Based on these results, cellulose digestion by F. succinogenes S85 appears to be constrained by cellulose surface area rather than cellulase activity per se.
Commercial baker's yeast stability as affected by intracellular content of trehalose, dehydration procedure and the physical properties of external matrices by P. Cerrutti; M. Segovia de Huergo; M. Galvagno; C. Schebor; M. del Pilar Buera (pp. 575-580).
The effects of vacuum-drying and freeze- drying on the cell viability of a commercial baker's yeast, Saccharomyces cerevisiae, strain with different endogenous contents of trehalose were analyzed. An osmotolerant Zygosaccharomyces rouxii strain was used for comparative purposes. Higher viability values were observed in cells after vacuum-drying than after freeze-drying. Internal concentrations of trehalose in the range 10–20% protected cells in both dehydration processes. Endogenous trehalose concentrations did not affect the water sorption isotherm nor the T g values. The effect of external matrices of trehalose and maltodextrin was also studied. The addition of external trehalose improved the survival of S. cerevisiae cells containing 5% internal trehalose during dehydration. Maltodextrin (1.8 kDa) failed to protect vacuum-dried samples at 40 °C. The major reduction in the viability during the freeze-drying process of the sensitive yeast cells studied was attributed to the freezing step. The suggested protective mechanisms for each particular system are vitrification and the specific interactions of trehalose with membranes and/or proteins. The failure of maltodextrins to protect cells was attributed to the fact that none of the suggested mechanisms of protection could operate in these systems.
Zinc biosorption by a zinc-resistant bacterium, Brevibacterium sp. strain HZM-1 by J. Taniguchi; H. Hemmi; K. Tanahashi; N. Amano; T. Nakayama; T. Nishino (pp. 581-588).
A zinc-resistant bacterium, Brevibacterium sp. strain HZM-1 which shows a high Zn2+-adsorbing capacity, was isolated from the soil of an abandoned zinc mine. Kinetic analyses showed that Zn2+ binding to HZM-1 cells follows Langmuir isotherm kinetics with a maximum metal capacity of 0.64 mmol/g dry cells and an apparent metal dissociation constant of 0.34 mM. The observed metal-binding capacity was one of the highest values among those reported for known microbial Zn2+ biosorbents. The cells could also adsorb heavy metal ions such as Cu2+. HZM-1 cells could remove relatively low levels of the Zn2+ ion (0.1 mM), even in the presence of large excess amounts (total concentration, 10 mM) of alkali and alkali earth metal ions. Bound Zn2+ ions could be efficiently desorbed by treating the cells with 10 mM HCl or 10 mM EDTA, and the Zn2+-adsorbing capacity of the cells was fully restored by treatment of the desorbed cells with 0.1 M NaOH. Thus, HZM-1 cells can serve as an excellent biosorbent for removal of Zn2+ from natural environments. The cells could grow in the presence of significant concentrations of ZnCl2 (at least up to 15 mM) and thus is potentially applicable to in situ bioremediation of Zn2+-contaminated aqueous systems.
Biodegradation of atrazine in sand sediments and in a sand-filter by S. J. Goux; M. Ibanez; M. Van Hoorick; P. Debongnie; S. N. Agathos; L. Pussemier (pp. 589-596).
The potential of a microbial consortium for treating waters contaminated with atrazine was considered. In conventional liquid culture, atrazine and its two dealkylated by-products were equally metabolised by the microbial consortium. Transient production of hydroxyatrazine was observed during atrazine catabolism, indicating that the catabolic pathway was similar to the one reported for isolates capable of atrazine mineralisation. This consortium was then inoculated to sediments sampled from an artificial recharge site. These sediments were contaminated by atrazine and diuron and exhibited only a slow endogenous herbicide dissipation. Inoculated microorganisms led to extensive atrazine degradation and survived for more than 10 weeks in the sediments. A rudimentary bioreactor was then setup using a soil core originating from the same recharge site. Degrading microorganisms rapidly colonised the core and expressed their degrading activity. The efficiency of the bioreactor was improved in the presence of spiked environmental surface waters. Atrazine degraders thus possibly benefited from the other organic sources in developing and expressing their activity. The microbial consortium did not initially exhibit the capacity to degrade diuron, which was used as reference compound. No change in this characteristic was detected throughout the study.
Screening of hexavalent chromium biosorbent from marine algae by D.-C. Lee; C.-J. Park; J.-E. Yang; Y.-H. Jeong; H.-I. Rhee (pp. 597-600).
A highly chromate-selective biosorbent with high adsorption capacity was found by examining the chromate adsorption capacities of 48 species of red, brown, or green marine algae sampled from the east coast of Korea. As a result of screening, a red marine alga showed excellent adsorption characteristics. It was identified as Pachymeniopsis sp. The timing of the sampling of Pachymeniopsis sp. did not affect the adsorption capacity of the alga but the optimum period for mass collection was April–May. The alga also showed high selectivity for chromate and its adsorption capacity for other heavy metal ions such as cadmium and manganese was relatively low. An investigation of the adsorption isotherm of Pachymeniopsis sp. as a dried powder for chromate adsorption at 25 °C showed Langmuir-type dependence. The maximum chromate adsorption capacity of the selected alga was about 225 mg/g. The desorption of adsorbed chromate from Pachymeniopsis sp. was done by treating samples with 1 N NaOH. It was confirmed that ion exchange type adsorption was observed with anion exchangers but not with cation exchangers. Therefore it is believed that the chromate adsorption is based on the anionic exchange of Pachymeniopsis sp.