Selected Chitinase Genes in Cultured and Uncultured Marine Bacteria in the alpha - and gamma -Subclasses of the Proteobacteria

doi:10.1128/AEM.66.3.1195-1201.2000

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Applied and Environmental Microbiology, March 2000, p. 1195-1201, Vol. 66, No. 3
0099-2240/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Selected Chitinase Genes in Cultured and Uncultured Marine Bacteria in the $alpha$ - and $gamma$ -Subclasses of the Proteobacteria

Matthew T. Cottrell, Daniel N. Wood, Liying Yu, and David L. Kirchman^*

College of Marine Studies, University of Delaware, Lewes, Delaware 19958

Received 14 October 1999/Accepted 29 December 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

PCR primers were patterned after chitinase genes in four $gamma$ -proteobacteria in the families Alteromonadaceae and Enterobacteriaceae(group I chitinases) and used to explore the occurrence and diversityof these chitinase genes in cultured and uncultured marine bacteria.The PCR results from 104 bacterial strains indicated that thistype of chitinase gene occurs in two major groups of marine bacteria, $alpha$ - and $gamma$ -proteobacteria, but not the Cytophaga-Flavobacter group.Group I chitinase genes also occur in some viruses infecting arthropods.Phylogenetic analysis indicated that similar group I chitinasegenes occur in taxonomically related bacteria. However, the overallphylogeny of chitinase genes did not correspond to the phylogenyof 16S rRNA genes, possibly due to lateral transfer of chitinasegenes between groups of bacteria, but other mechanisms, such asgene duplication, cannot be ruled out. Clone libraries of chitinasegene fragments amplified from coastal Pacific Ocean and estuarineDelaware Bay bacterioplankton revealed similarities and differencesbetween cultured and uncultured bacteria. We had hypothesizedthat cultured and uncultured chitin-degrading bacteria would bevery different, but in fact, clones having nucleotide sequencesidentical to those of chitinase genes of cultured $alpha$ -proteobacteriadominated both libraries. The other clones were similar but notidentical to genes in cultured $gamma$ -proteobacteria, including vibriosand alteromonads. Our results suggest that a closer examinationof chitin degradation by $alpha$ -proteobacteria will lead to a betterunderstanding of chitin degradation in theocean.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Surveys of microbial diversity without cultivation have discovered types of microbes not detected in culture-based studieslargely because <1% of the microorganisms observable in naturecan be cultivated using standard techniques (3). Furthermore,the few bacteria that can be cultured appear to be very differentfrom uncultured bacteria, based on comparisons of 16S rRNA genesequences. Consequently, the lack of closely related culturedrepresentatives raises questions about the metabolic capacitiesof the uncultured bacteria and the role of these microbes in specificbiogeochemical processes. Some physiological capacities are restrictedto specific taxonomic groups of microbes, for example, oxygenicphotoautotrophy in cyanobacteria, but in general, the relationshipbetween the taxonomy of uncultured bacteria and many biogeochemicallyinteresting capacities is not known. One approach for exploringthe metabolic capacities of uncultured bacteria is to examinegenes encoding enzymes involved in specific biogeochemical processes.This approach is a step toward identifying microbial groups drivingthose processes and determining whether the metabolism of culturedbacteria adequately represents the metabolic capacities of unculturedbacteria.

Previous studies have already examined several genes encoding enzymes mediating biogeochemical reactions in C, N, and S cyclesand have compared these genes in cultured and uncultured bacteriain natural microbial communities. These enzymes, genes, and bacteriainclude the nitrogen-fixing enzyme (nifH) (42) in nitrogen-fixingbacteria, nitrite reductase (nirK and nirS) and nitrous oxidereductase (nosZ) in denitrifying bacteria (5, 18), particulatemethane monooxygenase (pmoA) and methanol dehydrogenase (mxaF)found in bacteria using C₁ and methylated compounds (30, 31),and dissimilatory bisulfite reductase (dsv) in sulfate-reducingbacteria (7). In most cases, the genes of cultured and unculturedbacteria were not identical, suggesting that cultured bacteriado not adequately model biogeochemical processes driven by unculturedbacteria.

The genes that have been examined to date in uncultured bacteria are essential to the microbes' survival, even if only underselected conditions (e.g., denitrification genes are essentialonly under anoxic conditions). In contrast, little is known aboutnonessential genes in uncultured bacteria. Variation and correlationof nonessential genes with rRNA gene phylogeny might differ fromthose of essential genes. Differences could arise from variousmechanisms, including different rates of evolution, gene duplication,and lateral gene transfer (9). There seems to be less resistanceto lateral transfer of nonessential genes than essential genes(9).

Genes encoding chitinases and other glycosyl hydrolases may be particularly interesting examples of nonessential genes inuncultured bacteria, since previous work has already suggestedthat the evolution of these enzymes has been impacted by lateralgene transfer (10). Chitinases are probably not essential forheterotrophic bacteria living in most environments, includingthe oceans, where chitin is very abundant (25), because manyother organic carbon sources are available. Although perhaps nonessentialto an individual bacterium, hydrolysis of chitin and other high-molecular-weightbiopolymers by hydrolases is still an essential first step inthe degradation of organic material in nature. Many types of culturedbacteria and archaea are known to hydrolyze chitin (17, 21),but the identity of uncultured bacteria degrading chitin in natureis unknown. Chitinase genes cloned directly from uncultured marinemicroorganisms suggested the presence of a large pool of unculturedchitin-degrading bacteria in aquatic systems (8).

Information on bacterial chitinase genes is largely restricted to cultured $gamma$ -proteobacteria and gram-positive bacteria. Since $gamma$ -proteobacteria are widespread in the ocean (11), comparingchitinase genes in cultured and uncultured bacteria in this phylogeneticgroup should be informative. In contrast, gram-positive bacteriaare quite rare in seawater (11). To access chitinase genes inuncultured $gamma$ -proteobacteria and potentially in other bacteria,it may be possible to use a PCR-based approach with oligonucleotideprimers patterned after conserved nucleotide sequences of chitinasegenes in cultured bacteria. However, it is not possible to designa single pair of PCR primers that will amplify even all $gamma$ -proteobacterialchitinases because they are too different. Svitil and Kirchman(38) did identify 13 and 15 consensus amino acids in the catalyticand chitin-binding domains of bacterial chitinases, respectively.But since PCR primers require adjacent identical nucleotides oramino acids, the conserved regions in bacterial chitinases areinsufficient for designing PCR primers that would amplify allbacterial chitinases. An alternative approach would be to targetselected subsets of bacterial chitinases. One such subset is groupI, which has the highest average percent similarity of the fivechitinase groups classified by Svitil and Kirchman (38).

Our goals were to compare the group I chitinase genes of cultured and uncultured bacteria and to examine the relationshipbetween the phylogeny of these chitinase genes and the phylogenyof 16S rRNA genes. We hypothesized that PCR primers for groupI chitinase genes would amplify chitinase genes of other culturedand uncultured $gamma$ -proteobacteria. It was unclear if more distantlyrelated bacteria possess this type of chitinase as well. We alsoexpected that chitinase genes of cultured and uncultured chitin-degradingbacteria would differ and that chitinase gene phylogeny wouldnot follow the phylogeny of 16S rRNA genes. In fact, we foundthat a few chitinases from uncultured bacteria were very similar,and in some cases identical, to those in cultured bacteria, butoverall, the phylogeny of chitinase genes differed from 16S rRNAphylogeny.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Isolation and characterization of bacterial strains. Surface seawater was collected from the Indian River Inlet on the Atlantic coast of Delaware and the University of Delawaredock at the Roosevelt Inlet, situated 8 km inside the DelawareBay estuary. Bacterial strains were isolated on 1.5% agar preparedusing unenriched seawater and seawater enriched with R2A nutrients,which include 0.5 g each of yeast extract, peptone, Casamino Acids,and dextrose per liter and 0.3 g of sodium pyruvate per liter(37). Plates were incubated at 20 to 25°C and inspected dailyfor growth. Strains were purified by two iterations of streakingon agar. Strains were analyzed by using a mixture of the restrictionenzymes RsaI and HhaI (32) to digest 16S rRNA genes amplifiedusing primers EubA and EubB (12). Strains having different restrictionpatterns were used in subsequent analyses. Bacterial strains wereclassified phylogenetically using fluorescent in situ hybridizationof fluorochrome-labeled rRNA probes specific for $alpha$ -proteobacteria,Alf1b (29), $beta$ -proteobacteria, Bet42a (29), $gamma$ -proteobacteria,Gam42a (29), the Cytophaga-Flavobacter cluster (28), and gram-positivebacteria having high DNA G+C content (35). Established hybridizationconditions were used for each probe (41). One strain producingambiguous results using fluorescent in situ hybridization wascharacterized by sequencing of the 16S rRNAgene.

Strains were screened for the ability to produce clearing zones on unenriched seawater agar and R2A-enriched seawater agarcontaining colloidal chitin. Cultures were also assayed for hydrolysisof the fluorogenic chitin analogue 4-methylumbelliferyl- $beta$ -D-N,N'-diacetylchitobioside.For this analysis, cultures were grown on R2A-enriched seawaterbroth and artificial seawater enriched with 50 mg of chitin oligomers(Vector Labs) per liter 10 mM NH₃Cl, and 2 mM NaH₂PO₄.

Isolation of environmental DNA. Coastal Pacific Ocean water was collected from a depth of 1 m at Station 5, located 60 km off the coast of Oregon (salinityequal to 28 ppt) in July 1997. Delaware Bay estuarine water wascollected at a depth of 0.5 m from Station 16, located 80 km upstreamfrom the mouth of the estuary (20) (salinity equal to 2.0 ppt)in September 1997. The coastal Pacific sample (10 liter) was filteredthrough a 1-µm-pore-size filter, and bacteria were collected on0.2-µm Gelman Supor filters. The Delaware Bay sample (10 liters)was filtered through a 1-µm filter, and bacteria were collectedusing a Millipore Sterivex-GV filtration cartridge (0.22 µm).The samples were stored frozen at $-$ 80°C in a storage buffer (13).Frozen samples were thawed, and the cells were lysed using sodiumdodecyl sulfate and proteinase K. The lysate was extracted sequentiallywith phenol-chloroform and chloroform. The nucleic acids wereprecipitated with ethanol and further purified using cetyltrimethylammoniumbromideextraction.

PCR primer design. We identified conserved amino acids in the chitinases encoded by the chiA genes of Alteromonas sp. (40), Aeromonas caviae(36), Serratia marcescens (22), and Enterobacter agglomerans(19). The conserved regions were in the putative catalytic andchitin-binding domains and a region with no known function (38).The forward primer was based on conserved amino acids in the catalyticregion at amino acid 260 of ChiA in Alteromonas sp. strain 0-7.The reverse primer bound to a conserved region with no known functionat amino acid 571 of chitinase A in the Alteromonas strain. Deoxyinosineresidues in the third position of codons were used to accommodateevery codon for all amino acids in the targeted regions withoutincreasing degeneracy of the primers. This group of chitinasegenes is called group I (38).

Clone library construction and screening. Group I chitinase genes were amplified from DNA of coastal Pacific Ocean and Delaware Bay bacterioplankton using 25-µl PCRmixtures containing 4 ng of template DNA per µl, the four deoxynucleosidetriphosphates (dTTP, dCTP, dGTP, and dATP) at 0.2 mM each, 1.5mM MgCl₂, 1 µM each primer, and 2.5 U of Taq DNA polymerase (Promega).Thermal cycling conditions included 1 min of denaturation at 94°C,1 min of primer annealing at 50°C, and 3 min of primer extensionat 72°C. This cycle was repeated 35 times. PCR products were clonedby using the TOPO-TA cloning kit with the pCR 2.1 vector (Invitrogen)following the manufacturer's protocol. Approximately 60 recombinantclones were screened for full-size inserts (approximately 900bp) by transferring small aliquots of cells to PCR mixtures containingthe group I chitinase gene primers and PCR amplified using theconditions described above. The PCR products were cut with a mixtureof restriction enzymes HhaI and RsaI. The restriction fragmentswere separated by agarose gel electrophoresis using 2% Metaphore(FMC) agarose. Clones having identical restriction patterns weregrouped together into clonefamilies.

Nucleotide sequencing. Nucleotide sequencing was performed using an ABI PRISM 310 (Perkin-Elmer) genetic analyzer and ABI PRISM Big Dye terminatorcycle sequencing reagent. Double-stranded DNA templates were preparedusing the manufacturer's alkaline-lysis procedure. M13 forwardand reverse sequencing primers and internal sequencing primerswere used to obtain the complete nucleotide sequences of bothDNA strands of one clone from each clone family. Deduced aminoacid sequences were analyzed by using the BLASTX (2)tool.

Phylogenetic analysis. Similarity between chitinases (percent identical aligned amino acids) was determined from conceptual translations of openreading frames. Percentages of identical aligned nucleotides werecompared for sequences having identical deduced amino acid sequences.Nucleotides were aligned using the corresponding amino acid alignmentmade using CLUSTAL in Sequence Navigator version 1.01 (Perkin-Elmer).Phylogenetic analysis was performed using SEQBOOT, DNADIST (Kimura2-parameter model), NEIGHBOR, and CONSENSUS in PHYLIP version3.527.

Nucleotide sequence accession numbers. The nucleotide sequences described in this paper have been deposited in GenBank under accession no. AF193488 to AF193506.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Primer design. Amino acid sequences of bacterial chitinase genes are very different, except for the catalytic and chitin-binding domains,but variation in even these two domains is too great for a singlePCR primer set to match all bacterial chitinase genes. An alternativeapproach is to design PCR primers for sets of similar bacterialchitinases. The primers designed for this study were based ondeduced amino acid sequences of chitinases in four $gamma$ -proteobacteria.This set of chitinases has been designated group I (38).

The forward PCR primer (IICRFORB) was patterned after conserved amino acids in the catalytic domain of group I chitinase genes,including the chiA genes in Alteromonas sp., A. caviae, S. marcescens,and E. agglomerans (Fig. 1). The chitin-binding domains were toovariable for a PCR primer, but alignment of the complete deducedamino acid sequences of these four group I chitinase genes revealed12 adjacent, conserved amino acids about 300 amino acids downstreamfrom the forward priming site. A reverse primer (GRPI571AR) waspatterned after seven of the conserved amino acids in this region(Fig. 1). The forward and reverse primers are degenerate 20-meroligonucleotides incorporating every codon for the conserved aminoacids. The oligonucleotides IICRFORB and GRPI571AR are referredto here as the group I primers.

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FIG. 1. Aligned nucleotide and deduced amino acid sequences used to design forward and reverse group I PCR primers IICRFORB and GRPI571AR, respectively. Dots indicate the same nucleotides or amino acids as in the Alteromanas sp. strain 0-7 sequence. The forward priming site is located in the hydrolytic domain, while the reverse priming site is approximately 900 bp downstream. The nucleotide sequences of the chiA genes of Alteromonas sp. (39), A. caviae (35), S. marcescens (22), and E. agglomerans (19) were obtained from GenBank.

Specificity of group I primers. The group I primers yielded products having the predicted size (900 bp) from genomic DNA of 18 $gamma$ -proteobacteria out of thetotal of 38 strains tested, including the strains used to designthe primers (Table 1). BLASTX analysis indicated that the deducedamino acid sequences of amplification products from $gamma$ -proteobacteriawere >69% similar to known chitinase genes. Four of the 24 $alpha$ -proteobacteriatested yielded 900-bp products having deduced amino acid sequencessimilar to those of chitinase genes (Table 1). All of the $gamma$ -proteobacteriaamplifying with the group I primers were chitinolytic, but noneof the four positive $alpha$ -proteobacteria proved to be chitinolyticunder the conditions tested. No amplification was obtained fromthe four chitinolytic $alpha$ -proteobacteria.

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TABLE 1. Bacterial strains tested for amplification with PCR primers for group I chitinase genes^a

None of the 6 $beta$ -proteobacteria, 30 Cytophaga-Flavobacter bacteria, or 6 gram-positive bacteria we tested yielded 900-bp amplificationproducts (Table 1), even though more than half of the strainsin each group were chitinolytic. Less than 10% of all strainsyielded nonspecific amplification products, i.e., a product smalleror larger than 900 bp. These nonspecific products had deducedamino acid sequences substantially different from those ofchitinases.

Construction and composition of clone libraries. The occurrence of group I chitinase genes in naturally occurring bacteria was investigated using DNA extracted from bacterioplanktonin the coastal Pacific Ocean and Delaware Bay. Bacterial communityDNA from coastal and estuarine environments yielded the expected900-bp products (Fig. 2). The Pacific sample required concentratingbefore cloning (Fig. 2A), while ample product was generated fromthe Delaware Bay sample without a concentrating step (Fig. 2B).

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FIG. 2. Ethidium bromide-stained agarose gel of PCR amplification products obtained with the group I primers. (A) Amplification of chitinase genes from microbial DNA collected from the coastal Pacific Ocean. Lanes: 1, molecular size markers; 2, PCR with bacterial community DNA; 3, PCR with bacterial community DNA concentrated by ultrafiltration; 4, PCR with Alteromonas sp. strain 0-7 DNA; 5, no-template control. (B) Amplification of chitinase genes from microbial DNA collected from the Delaware Bay estuary. Lanes: 1, molecular size markers; 2, PCR with bacterial community DNA; 3, PCR with Alteromonas sp. strain 0-7 DNA; 5, no-template control.

Sixty clones from the Pacific library treated with a mixture of restriction enzymes HhaI and RsaI yielded 14 different bandingpatterns. Clones sharing the same restriction pattern were assembledinto clone families (Table 2). Twenty-six clones representing43% of the Pacific library were assigned to clone family A (Table2 and Fig. 3). Clone family B, comprised of nine clones, represented15% of the library, while clone families C to N each containedseven or fewer clones. One clone from each clone family was completelysequenced and analyzed using BLASTX to determine its similarityto known chitinases. Seven of the 14 clone families in the Pacificlibrary encoded proteins that were greater than 69% similar toknown chitinases (Table 2 and Fig. 3). The seven chitinase clonefamilies contained 82% of the clones in the library. Clone familiesnot representing chitinase genes comprised half of the clone familiesbut only 18% of the clones in the library.

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TABLE 2. Characteristics of cloned group I chitinase gene fragments amplified from microbial DNA from the coastal Pacific Ocean and Delaware Bay^a

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FIG. 3. Frequency distribution of clone families in the coastal Pacific Ocean library. The percentage of clones in each family was calculated relative to the total number of clones in the library.

Digestion of 57 clones in the Delaware Bay library with a mixture of restriction enzymes HhaI and RsaI produced nine differentrestriction patterns. Clones having identical restriction patternswere segregated into nine clone families (Table 2), includingthree (A, B, and C) that occurred in the Pacific library as well.Clone families A and B, which dominated the Pacific library, alsocomprised the bulk of the Delaware Bay library (Table 2 and Fig.4). Thirty clones representing 53% and 17 clones representing30% of the Delaware Bay library were assigned to clone familiesA and B, respectively. Two clones were assigned to clone familyC, which occurred in both libraries. Six clone families (O, P,Q, R, S, and T) represented by two or fewer clones were presentonly in the Delaware Bay library.

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FIG. 4. Frequency distribution of clone families in the Delaware Bay estuary library. The percentage of clones in each family was calculated relative to the total number of clones in the library.

Sequencing of one clone in each clone family of the Delaware Bay library revealed that 89% of the clones in the Delaware Baylibrary encoded proteins that were >69% similar to known chitinases(Table 2). Five of the nine clone families (A, B, P, S, and T)represented chitinase genes, whereas four clone families (C, O,Q, and R) did not encodechitinases.

Similarities among chitinase genes. Chitinase genes in taxonomically related, cultured bacteria were similar, but chitinase phylogeny did not correlate completelywith 16S rRNA phylogeny (Fig. 5). Chitinase genes in culturedVibrio species were greater than 77% similar to each other, andphylogenetic analysis placed them in a clade separate from chitinasesof other cultured $gamma$ -proteobacteria (Fig. 5). Chitinases in membersof the families Alteromonadaceae and Enterobacteriaceae were lessthan 77 and 63% similar to Vibrio chitinases, respectively. Similaritywas greater than 72% within clades of chitinases in Alteromonadaceae,Enterobacteriaceae, and $alpha$ -proteobacteria. These assignments aresupported by bootstrap values of 57 to 100 (Fig. 5).

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FIG. 5. Additive phylogenetic tree of group I chitinase genes from cultured and uncultured bacteria and viruses of arthropods. The neighbor-joining analysis used a chitinase gene from B. licheniformis (GenBank accession no. U71214) as the outgroup. $alpha$ -Proteobacteria (15, 16) and $gamma$ -proteobacteria were isolated from coastal and estuarine environments. Shewanella baltica was isolated from the Baltic Sea (42). The nucleotide sequences of the chitinase genes of reference strains of Pseudoalteromonas sp. (38), Enterobacter sp. (33), B. mori NPV (23), Autographa californica NPV (4), Orgyia pseudotsugata NPV (1), Helicoverpa zea NPV (26), Helicoverpa armigera NPV (GenBank accession no. AF114795), Lymantria dispar NPV (25), and Cydia pomonella granulovirus (GV) (24) were obtained from GenBank. Bootstrap values are indicated at the nodes separating the major groups. Genes from uncultured bacteria are underlined and are designated by a station and clone number (e.g., 5-40). The scale bar indicates the amount of genetic change measured as the number of nucleotide substitutions per site.

Group I chitinases occur in viruses infecting arthropods. The viral group I chitinases were more diverse than the bacterialgroups revealed by our analysis and were 62 to 96% similar toeach other. Viral chitinases were only 45 to 64% similar to groupI chitinases from bacteria. However, these viral chitinases aremore similar to bacterial group I chitinases than other bacterialchitinases are to bacterial group I chitinases. For example, bacterialgroup I chitinases are only 32% similar, on average, to the chitinaseof Bacillus licheniformis (GenBank accession no. U71214).

Similarity between chitinases of uncultured and cultured bacteria ranged from 52 to 100% at the amino acid level (Fig. 5).At one extreme, clone 5-8 was identical at both the amino acidand nucleotide levels to the chitinases of $alpha$ -proteobacteria includingstrain EE36 (14) and Sagittula stellata strain E37 (15) inthe Roseobacter group. Clone 5-27 was also very (>97%) similarto the chitinase genes of $alpha$ -proteobacteria. In contrast, the chitinasesof uncultured bacteria represented by clones 5-5, 5-37, 5-40,16-15, and 16-23 were most (84 to 89% at the amino acid level)similar to the chitinases of cultured Vibrio species but nonewere identical to that of a cultured strain. The node separatingthis clade of chitinase genes in uncultured bacteria from theclade of chitinases in cultured Vibrio species had a bootstrapvalue of 76 (Fig. 5). Finally, the chitinases of uncultured bacteriarepresented by clones 5-63 and 5-26 were most similar (76 to 83%)to chitinases of cultured bacteria including Colwellia sp., Alteromonassp., and Pseudoalteromonassp.

Group I chitinase genes in uncultured bacteria from the coastal Pacific and Delaware Bay were least similar to the chitinasegenes of cultured enterobacteria (<64% similar) and viruses infectingarthropods (<58% similar). No genes of uncultured bacteria werein clades comprised of the family Enterobacteriaceae or virusesinfecting arthropods (Fig. 5).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Although many types of cultured bacteria are known to degrade chitin and chitin degradation is widespread in nature, the relationshipbetween uncultivated chitin-degrading bacteria and cultured strainsis unknown. Since phylogenetic analysis of 16S rRNA genes indicatesthat cultured and uncultured bacteria differ greatly (37), wehypothesized that uncultivated chitin-degrading bacteria are probablydifferent as well. We used a pair of PCR primers patterned afterchitinase genes initially identified in $gamma$ -proteobacteria to explorethe diversity of chitinase genes in uncultured bacteria from twocontrasting marine environments. It was necessary to begin withprimers based on chitinase genes in $gamma$ -proteobacteria because thisis the only phylogenetic group of bacteria, aside from gram-positivebacteria, which are quite rare in the ocean (11), for whichchitinase gene sequences are available. As predicted, most ofthe chitinase genes amplified from natural bacterial assemblagesusing the group I primers were different from the chitinase genesof cultured strains. However, some chitinase genes from unculturedbacteria were very similar and even identical to group I chitinasegenes of $alpha$ -proteobacteria. Phylogenetic analysis of group I chitinasesof cultured strains revealed clusters of similar genes in taxonomicallyrelated bacteria. Still, the overall phylogeny of chitinase genesdid not coincide with 16S rRNA phylogeny. Most prominently inthe neighbor-joining analysis (Fig. 5), as well as in parsimonyand maximum-likelihood analyses, the cluster of genes from $alpha$ -proteobacteriaformed a clade within the larger clade of genes from $gamma$ -proteobacteria,including alteromonads andvibrios.

Testing of the group I primers on various cultured strains revealed that group I chitinase genes occur, as expected, in manytypes of $gamma$ -proteobacteria, including Enterobacteriaceae, Aeromonas,Vibrio species, and various Alteromonadaceae, including strainsof Shewanella and Pseudoalteromonas (Table 1). Unexpectedly,amplification products were obtained from strains in the Roseobactergroup (Table 1), indicating that culturable marine $alpha$ -proteobacteriapossess group I chitinase genes. Of the 24 cultured $alpha$ -proteobacteriastrains we examined, only 1 produced a clearing zone on mediacontaining colloidal chitin while 3 other strains hydrolyzed thefluorogenic chitin analogue 4-methylumbelliferyl- $beta$ -D-N,N'-diacetylchitobioside(D. L. Kirchman, M. T. Cottrell, L. Yu, and K. Dyit, unpublisheddata, 1999). However, none of the $alpha$ -proteobacteria amplifyingwith the group I primers expressed a chitinolytic phenotype (Table1). There are clearly aspects of chitin degradation by $alpha$ -proteobacteriathat are not understood. Chitin degradation in $alpha$ -proteobacteriahas not been extensively studied, but an examination of unculturedbacteria using fluorescence in situ hybridization of 16S rRNA-directedoligonucleotide probes combined with microautoradiography (6)suggested that $alpha$ -proteobacteria are involved in chitin degradationin estuarine and coastalwaters.

The most abundant type of group I chitinase gene amplified from estuarine and coastal Pacific Ocean bacterioplankton DNA was>98% similar to genes in cultured members of the Roseobacter group.In fact, the nucleotide sequences of clones in clone family Awere identical to those of strain EE36 and S. stellata strainE37 in the Roseobacter group. More than half of the clones inthe coastal Pacific and Delaware Bay libraries represent chitinasegenes most similar to those in cultured $alpha$ -proteobacteria, suggestingthat chitin hydrolysis by culturable $alpha$ -proteobacteria may adequatelymodel hydrolysis by unculturable $alpha$ -proteobacteria in the coastalPacific Ocean and Delaware Bay. In contrast, none of the chitinasegenes from uncultured bacteria were identical to those of $gamma$ -proteobacteria.These data suggest that chitin hydrolysis by these unculturedorganisms in the ocean is not adequately represented by culturedbacteria in thesegroups.

Chitinase gene phylogeny only partially followed the phylogeny of 16S rRNA genes, which currently defines bacterial phylogeny,in particular, the various classes of proteobacteria. Our resultsshow a closer relationship between chitinase genes of vibrios( $gamma$ -proteobacteria) and $alpha$ -proteobacteria than between Vibrio chitinasesand other $gamma$ -proteobacterial chitinases, such as those in somealteromonads. The deviation in chitinase gene phylogeny from 16SrRNA gene phylogeny may due to lateral gene transfer. Although16S rRNA genes are presumed to be fairly resistant to lateraltransfer, evidence is accumulating that transfer of nonessentialgenes, e.g., chitinase genes, between groups of bacteria is moreprevalent than previously realized. In fact, microbial genomesappear to be patchworks of genes exchanged by lateral transfer(9). If this is so, the phylogeny of chitinase genes may notbe particularlyexceptional.

Lateral transfer of chitinase genes is an attractive hypothesis to explain the different phylogenetic relationships betweengroup I chitinase and 16S rRNA genes. However, other mechanismscannot be excluded. The phylogenetic relationships of similarchitinase genes could differ from the 16S rRNA tree if the chitinasegenes are actually a mixture of different genes that arose froma gene duplication event (33). The 16S rRNA and chitinase genetrees would likely differ if the 16S rRNA gene reflects subsequentbacterial speciation decoupled from independent evolution of thechitinase genes. The 16S rRNA and chitinase gene trees would onlymatch if all of the chitinase genes from bacteria having the corresponding16S rRNA genes were compared. It is not possible to link definitivelythe chitinase and 16S rRNA genes in unculturedbacteria.

In the case of arthropod viruses, however, lateral gene transfer remains the most plausible explanation. The similarity ofchitinases in bacteria and viruses alone provides a compellingargument for the idea that viruses obtained chitinase genes frombacteria. Furthermore, there is little evidence suggesting thatthese viruses acquired chitinase genes from their arthropod hosts.For example, the chitinase of Bombyx mori nuclear polyhedrosisvirus (NPV) is 64% identical to ChiA of Enterobacter sp. strainG-1 at the amino acid level while the arthropod host and viralchitinase genes are not very similar, sharing only 24% identicalaligned amino acids. In addition, the host gene lacks the primingsites for the group I chitinase primers. The viral group I chitinasegenes probably originated in bacteria, not the arthropodhost.

Group I chitinase genes provide an interesting perspective for examining the diversity of hydrolytic enzymes involved in organicmatter degradation, the evolution of bacterial chitinase genes(38), and the relationship between chitinases of cultured anduncultured bacteria. Chitinase genes of uncultured microbes wereboth similar to and different from those of cultured bacteria.The most surprising similarity was between chitinase genes inuncultured bacteria and cultured $alpha$ -proteobacteria. Culture-basedstudies give little indication that $alpha$ -proteobacteria are importantchitin degraders in aquatic systems, but our results suggest thatexploration of the chitin-degrading capacities of uncultured $alpha$ -proteobacteriawill lead to a better understanding of chitin degradation in theocean.

	ACKNOWLEDGMENTS

This research was supported by the U.S. Department of Energy. Collection of the samples was supported by the National ScienceFoundation.

We thank Mary Ann Moran, Åke Hagström, Wietse de Boer, Ingrid Brettar, and Manfred Höfle for donating bacterialstrains.

	FOOTNOTES

^* Corresponding author. Mailing address: College of Marine Studies, University of Delaware, 700 Pilottown Rd., Lewes, DE 19958.Phone: (302) 645-4375. Fax: (302) 645-4028. E-mail: kirchman{at}udel.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Ahrens, C. H., R. L. Q. Russell, C. J. Funk, J. T. Evans, S. H. Harwood, and G. F. Rohrmann. 1997. The sequence of the Orgyia pseudotsugata multinucleocapsid nuclear polyhedrosis virus genome. Virology 229:381-399[CrossRef][Medline].

2. Altschul, S. F., W. Gish, W. Miller, E. W. Myers, and D. J. Lipman. 1990. Basic local alignment search tool. J. Mol. Biol. 215:403-410[CrossRef][Medline].

3. Amann, R. I., W. Ludwig, and K.-H. Schleifer. 1995. Phylogenetic identification and in situ detection of individual microbial cells without cultivation. Microbiol. Rev. 59:143-169[Abstract/Free Full Text].

4. Ayres, M. D., S. C. Howard, J. Kuzio, M. Lopezferber, and R. D. Possee. 1994. The complete DNA sequence of Autographa californica nuclear polyhedrosis virus. Virology 202:586-605[CrossRef][Medline].

5. Braker, G., A. Fesefeldt, and K. P. Witzel. 1998. Development of PCR primer systems for amplification of nitrite reductase genes (nirK and nirS) to detect denitrifying bacteria in environmental samples. Appl. Environ. Microbiol. 64:3769-3775[Abstract/Free Full Text].

6. Cottrell, M. T., and D. L. Kirchman. Natural assemblages of marine proteobacteria and Cytophaga-Flavobacter consuming low- and high-molecular-weight dissolved organic matter. Appl. Environ. Microbiol., in press.

7. Cottrell, M. T., and S. C. Cary. 1999. Diversity of dissimilatory bisulfite reductase genes of bacteria associated with the deep-sea hydrothermal vent polychaete annelid Alvinella pompejana. Appl. Environ. Microbiol. 65:1127-1132[Abstract/Free Full Text].

8. Cottrell, M. T., J. A. Moore, and D. L. Kirchman. 1999. Chitinases from uncultured marine microorganisms. Appl. Environ. Microbiol. 65:2553-2557[Abstract/Free Full Text].

9. Doolittle, W. F. 1999. Phylogenetic classification and the universal tree. Science 284:2124-2128[Abstract/Free Full Text].

10. Garcia-Vallvé, S., J. Palau, and A. Romeu. 1999. Horizontal gene transfer in glycosyl hydrolases inferred from codon usage in Escherichia coli and Bacillus subtilis. Mol. Biol. Evol. 16:1125-1134[Abstract].

11. Giovannoni, S., and M. Rappé. 2000. Evolution, diversity and molecular ecology of marine prokaryotes, p. 47-84. In D. L. Kirchman (ed.), Microbial ecology of the oceans. John Wiley & Sons, Inc., New York, N.Y.

12. Giovannoni, S. J. 1991. The polymerase chain reaction, p. 177-203. In E. Stackebrandt, and M. Goodfellow (ed.), Nucleic acid techniques in bacterial systematics. Wiley, New York, N.Y.

13. Giovannoni, S. J., E. F. DeLong, T. M. Schmidt, and N. R. Pace. 1990. Tangential flow filtration and preliminary phylogenetic analysis of marine picoplankton. Appl. Environ. Microbiol. 56:2572-2575[Abstract/Free Full Text].

14. González, J. M., W. B. Whitman, R. E. Hodson, and M. A. Moran. 1996. Identifying numerically abundant culturable bacteria from complex communities: an example from a lignin enrichment culture. Appl. Environ. Microbiol. 62:4433-4440[Abstract].

15. González, J. M., F. Mayer, M. A. Moran, R. E. Hodson, and W. B. Whitman. 1997. Sagittula stellata gen. nov., sp. nov., a lignin-transforming bacterium from a coastal environment. Int. J. Syst. Bacteriol. 47:773-780[Abstract/Free Full Text].

16. González, J. M., and M. A. Moran. 1997. Numerical dominance of a group of marine bacteria in the $alpha$ -subclass of the class Proteobacteria in coastal seawater. Appl. Environ. Microbiol. 63:4237-4242[Abstract].

17. Gooday, G. W. (ed.). 1979. A survey of polysaccharase production: a search for phylogenetic implications. Academic Press, London, England.

18. Hallin, S., and P. E. Lindgren. 1999. PCR detection of genes encoding nitrite reductase in denitrifying bacteria. Appl. Environ. Microbiol. 65:1652-1657[Abstract/Free Full Text].

19. Harpster, M. H., and P. Dunsmuir. 1989. Nucleotide sequence of the chitinase B gene of Serratia marcescens Qmb1466. Nucleic Acids Res. 17:5395[Free Full Text].

20. Hoch, M. P., and D. L. Kirchman. 1993. Seasonal and interannual variability in bacterial production and biomass in a temperate estuary. Mar. Ecol. Prog. Ser. 98:283-295[CrossRef].

21. Huber, R., J. Stohr, S. Hohenhaus, R. Rachel, S. Burggraf, H. Jannasch, and K. O. Stetter. 1995. Thermococcus chitonophagus sp. nov., a novel, chitin-degrading, hyperthermophilic archaeum from a deep-sea hydrothermal vent environment. Arch. Microbiol. 164:255-264[CrossRef].

22. Jones, J. D. G., K. L. Grady, T. V. Suslow, and J. R. Bedbrook. 1986. Isolation and characterization of genes encoding 2 chitinase enzymes from Serratia marcescens. EMBO J. 5:467-473[Medline].

23. Kamita, S. G., and S. Maeda. 1997. Sequencing of the putative DNA helicase-encoding gene of the Bombyx mori nuclear polyhedrosis virus and fine-mapping of a region involved in host range expansion. Gene 190:173-179[CrossRef][Medline].

24. Kang, W., M. Tristem, S. Maeda, N. E. Crook, and D. R. O'Reilly. 1998. Identification and characterization of the Cydia pomonella granulovirus cathepsin and chitinase genes. J. Gen. Virol. 79:2283-2292[Abstract].

25. Kirchman, D. L., and J. White. 1999. Hydrolysis and mineralization of chitin in the Delaware Estuary. Aquat. Microb. Ecol. 18:187-196[CrossRef].

26. Kuzio, J., M. N. Pearson, S. H. Harwood, C. J. Funk, J. T. Evans, J. M. Slavicek, and G. F. Rohrmann. 1999. Sequence and analysis of the genome of a baculovirus pathogenic for Lymantria dispar. Virology 253:17-34[CrossRef][Medline].

27. Le, T. H., T. Q. Wu, A. Robertson, D. Bulach, P. Cowan, K. Goodge, and D. Tribe. 1997. Genetically variable triplet repeats in a RING-finger ORF of Helicoverpa species baculoviruses. Virus Res. 49:67-77[CrossRef][Medline].

28. Manz, W., R. Amann, W. Ludwig, M. Vancanneyt, and K. H. Schleifer. 1996. Application of a suite of 16S rRNA-specific oligonucleotide probes designed to investigate bacteria of the phylum Cytophaga-Flavobacter-Bacteroides in the natural environment. Microbiology (Reading) 142:1097-1106[Abstract/Free Full Text].

29. Manz, W., R. Amann, W. Ludwig, M. Wagner, and K.-H. Schleifer. 1992. Phylogenetic oligodeoxynucleotide probes for the major subclasses of proteobacteria: problems and solutions. Syst. Appl. Microbiol. 15:593-600.

30. McDonald, I. R., and J. C. Murrell. 1997. The methanol dehydrogenase structural gene mxaF and its use as a functional gene probe for methanotrophs and methylotrophs. Appl. Environ. Microbiol. 63:3218-3224[Abstract].

31. McDonald, I. R., and J. C. Murrell. 1997. The particulate methane monooxygenase gene pmoA and its use as a functional gene probe for methanotrophs. FEMS Microbiol. Lett. 156:205-210[CrossRef][Medline].

32. Moyer, C. L., J. M. Tiedje, F. C. Dobbs, and D. M. Karl. 1996. A computer-simulated restriction fragment length polymorphism analysis of bacterial small-subunit rRNA genes: efficacy of selected tetrameric restriction enzymes for studies of microbial diversity in nature. Appl. Environ. Microbiol. 62:2501-2507[Abstract].

33. Page, R. D. M., and E. C. Holmes. 1998. Molecular evolution: a phylogenetic approach. Blackwell Science, Oxford, England.

34. Park, J. K., T. Okamoto, Y. Yamasaki, K. Tanaka, T. Nakagawa, M. Kawamukai, and H. Matsuda. 1997. Molecular cloning, nucleotide sequencing, and regulation of the chiA gene encoding one of chitinases from Enterobacter sp. G-1. J. Ferment. Bioeng. 84:493-501[CrossRef].

35. Roller, C., M. Wagner, R. Amann, W. Ludwig, and K. H. Schleifer. 1994. In situ probing of gram-positive bacteria with high DNA G+C content using 23S ribosomal-RNA-targeted oligonucleotides. Microbiology (Reading) 140:2849-2858[Abstract/Free Full Text].

36. Sitrit, Y., C. E. Vorgias, I. Chet, and A. B. Oppenheim. 1995. Cloning and primary structure of the chiA gene from Aeromonas caviae. J. Bacteriol. 177:4187-4189[Abstract/Free Full Text].

37. Suzuki, M. T., M. S. Rappé, Z. W. Haimberger, H. Winfield, N. Adair, J. Strobel, and S. J. Giovannoni. 1997. Bacterial diversity among small-subunit rRNA gene clones and cellular isolates from the same seawater sample. Appl. Environ. Microbiol. 63:983-989[Abstract].

38. Svitil, A. L., and D. L. Kirchman. 1998. A chitin-binding domain in a marine bacterial chitinase and other microbial chitinases: implications for the ecology and evolution of 1,4-beta-glycanases. Microbiology (Reading) 144:1299-1308[Abstract/Free Full Text].

39. Techkarnjanaruk, S., S. Pongpattanakitshote, and A. E. Goodman. 1997. Use of a promoterless lacZ gene insertion to investigate chitinase gene expression in the marine bacterium Pseudoalteromonas sp. strain S9. Appl. Environ. Microbiol. 63:2989-2996[Abstract].

40. Tsujibo, H., H. Orikoshi, H. Tanno, K. Fujimoto, K. Miyamoto, C. Imada, Y. Okami, and Y. Inamori. 1993. Cloning, sequence, and expression of a chitinase gene from a marine bacterium, Altermonas sp. strain O-7. J. Bacteriol. 175:176-181[Abstract/Free Full Text].

41. Zarda, B., D. Hahn, A. Chatzinotas, W. Schonhuber, A. Neef, R. I. Amann, and J. Zeyer. 1997. Analysis of bacterial community structure in bulk soil by in situ hybridization. Arch. Microbiol. 168:185-192[CrossRef].

42. Zehr, J. P., and D. G. Capone. 1996. Problems and promises of assaying the genetic potential for nitrogen fixation in the marine environment. Microb. Ecol. 32:263-281[Medline].

43. Ziemke, F., I. Brettar, and M. G. Höfle. 1997. Stability and diversity of the genetic structure of a Shewanella putrefaciens population in the water column of the central Baltic. Aquat. Microb. Ecol. 13:63-74.

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1.	Ahrens, C. H., R. L. Q. Russell, C. J. Funk, J. T. Evans, S. H. Harwood, and G. F. Rohrmann. 1997. The sequence of the Orgyia pseudotsugata multinucleocapsid nuclear polyhedrosis virus genome. Virology 229:381-399[CrossRef][Medline].
2.	Altschul, S. F., W. Gish, W. Miller, E. W. Myers, and D. J. Lipman. 1990. Basic local alignment search tool. J. Mol. Biol. 215:403-410[CrossRef][Medline].
3.	Amann, R. I., W. Ludwig, and K.-H. Schleifer. 1995. Phylogenetic identification and in situ detection of individual microbial cells without cultivation. Microbiol. Rev. 59:143-169[Abstract/Free Full Text].
4.	Ayres, M. D., S. C. Howard, J. Kuzio, M. Lopezferber, and R. D. Possee. 1994. The complete DNA sequence of Autographa californica nuclear polyhedrosis virus. Virology 202:586-605[CrossRef][Medline].
5.	Braker, G., A. Fesefeldt, and K. P. Witzel. 1998. Development of PCR primer systems for amplification of nitrite reductase genes (nirK and nirS) to detect denitrifying bacteria in environmental samples. Appl. Environ. Microbiol. 64:3769-3775[Abstract/Free Full Text].
6.	Cottrell, M. T., and D. L. Kirchman. Natural assemblages of marine proteobacteria and Cytophaga-Flavobacter consuming low- and high-molecular-weight dissolved organic matter. Appl. Environ. Microbiol., in press.
7.	Cottrell, M. T., and S. C. Cary. 1999. Diversity of dissimilatory bisulfite reductase genes of bacteria associated with the deep-sea hydrothermal vent polychaete annelid Alvinella pompejana. Appl. Environ. Microbiol. 65:1127-1132[Abstract/Free Full Text].
8.	Cottrell, M. T., J. A. Moore, and D. L. Kirchman. 1999. Chitinases from uncultured marine microorganisms. Appl. Environ. Microbiol. 65:2553-2557[Abstract/Free Full Text].
9.	Doolittle, W. F. 1999. Phylogenetic classification and the universal tree. Science 284:2124-2128[Abstract/Free Full Text].
10.	Garcia-Vallvé, S., J. Palau, and A. Romeu. 1999. Horizontal gene transfer in glycosyl hydrolases inferred from codon usage in Escherichia coli and Bacillus subtilis. Mol. Biol. Evol. 16:1125-1134[Abstract].
11.	Giovannoni, S., and M. Rappé. 2000. Evolution, diversity and molecular ecology of marine prokaryotes, p. 47-84. In D. L. Kirchman (ed.), Microbial ecology of the oceans. John Wiley & Sons, Inc., New York, N.Y.
12.	Giovannoni, S. J. 1991. The polymerase chain reaction, p. 177-203. In E. Stackebrandt, and M. Goodfellow (ed.), Nucleic acid techniques in bacterial systematics. Wiley, New York, N.Y.
13.	Giovannoni, S. J., E. F. DeLong, T. M. Schmidt, and N. R. Pace. 1990. Tangential flow filtration and preliminary phylogenetic analysis of marine picoplankton. Appl. Environ. Microbiol. 56:2572-2575[Abstract/Free Full Text].
14.	González, J. M., W. B. Whitman, R. E. Hodson, and M. A. Moran. 1996. Identifying numerically abundant culturable bacteria from complex communities: an example from a lignin enrichment culture. Appl. Environ. Microbiol. 62:4433-4440[Abstract].
15.	González, J. M., F. Mayer, M. A. Moran, R. E. Hodson, and W. B. Whitman. 1997. Sagittula stellata gen. nov., sp. nov., a lignin-transforming bacterium from a coastal environment. Int. J. Syst. Bacteriol. 47:773-780[Abstract/Free Full Text].
16.	González, J. M., and M. A. Moran. 1997. Numerical dominance of a group of marine bacteria in the $alpha$ -subclass of the class Proteobacteria in coastal seawater. Appl. Environ. Microbiol. 63:4237-4242[Abstract].
17.	Gooday, G. W. (ed.). 1979. A survey of polysaccharase production: a search for phylogenetic implications. Academic Press, London, England.
18.	Hallin, S., and P. E. Lindgren. 1999. PCR detection of genes encoding nitrite reductase in denitrifying bacteria. Appl. Environ. Microbiol. 65:1652-1657[Abstract/Free Full Text].
19.	Harpster, M. H., and P. Dunsmuir. 1989. Nucleotide sequence of the chitinase B gene of Serratia marcescens Qmb1466. Nucleic Acids Res. 17:5395[Free Full Text].
20.	Hoch, M. P., and D. L. Kirchman. 1993. Seasonal and interannual variability in bacterial production and biomass in a temperate estuary. Mar. Ecol. Prog. Ser. 98:283-295[CrossRef].
21.	Huber, R., J. Stohr, S. Hohenhaus, R. Rachel, S. Burggraf, H. Jannasch, and K. O. Stetter. 1995. Thermococcus chitonophagus sp. nov., a novel, chitin-degrading, hyperthermophilic archaeum from a deep-sea hydrothermal vent environment. Arch. Microbiol. 164:255-264[CrossRef].
22.	Jones, J. D. G., K. L. Grady, T. V. Suslow, and J. R. Bedbrook. 1986. Isolation and characterization of genes encoding 2 chitinase enzymes from Serratia marcescens. EMBO J. 5:467-473[Medline].
23.	Kamita, S. G., and S. Maeda. 1997. Sequencing of the putative DNA helicase-encoding gene of the Bombyx mori nuclear polyhedrosis virus and fine-mapping of a region involved in host range expansion. Gene 190:173-179[CrossRef][Medline].
24.	Kang, W., M. Tristem, S. Maeda, N. E. Crook, and D. R. O'Reilly. 1998. Identification and characterization of the Cydia pomonella granulovirus cathepsin and chitinase genes. J. Gen. Virol. 79:2283-2292[Abstract].
25.	Kirchman, D. L., and J. White. 1999. Hydrolysis and mineralization of chitin in the Delaware Estuary. Aquat. Microb. Ecol. 18:187-196[CrossRef].
26.	Kuzio, J., M. N. Pearson, S. H. Harwood, C. J. Funk, J. T. Evans, J. M. Slavicek, and G. F. Rohrmann. 1999. Sequence and analysis of the genome of a baculovirus pathogenic for Lymantria dispar. Virology 253:17-34[CrossRef][Medline].
27.	Le, T. H., T. Q. Wu, A. Robertson, D. Bulach, P. Cowan, K. Goodge, and D. Tribe. 1997. Genetically variable triplet repeats in a RING-finger ORF of Helicoverpa species baculoviruses. Virus Res. 49:67-77[CrossRef][Medline].
28.	Manz, W., R. Amann, W. Ludwig, M. Vancanneyt, and K. H. Schleifer. 1996. Application of a suite of 16S rRNA-specific oligonucleotide probes designed to investigate bacteria of the phylum Cytophaga-Flavobacter-Bacteroides in the natural environment. Microbiology (Reading) 142:1097-1106[Abstract/Free Full Text].
29.	Manz, W., R. Amann, W. Ludwig, M. Wagner, and K.-H. Schleifer. 1992. Phylogenetic oligodeoxynucleotide probes for the major subclasses of proteobacteria: problems and solutions. Syst. Appl. Microbiol. 15:593-600.
30.	McDonald, I. R., and J. C. Murrell. 1997. The methanol dehydrogenase structural gene mxaF and its use as a functional gene probe for methanotrophs and methylotrophs. Appl. Environ. Microbiol. 63:3218-3224[Abstract].
31.	McDonald, I. R., and J. C. Murrell. 1997. The particulate methane monooxygenase gene pmoA and its use as a functional gene probe for methanotrophs. FEMS Microbiol. Lett. 156:205-210[CrossRef][Medline].
32.	Moyer, C. L., J. M. Tiedje, F. C. Dobbs, and D. M. Karl. 1996. A computer-simulated restriction fragment length polymorphism analysis of bacterial small-subunit rRNA genes: efficacy of selected tetrameric restriction enzymes for studies of microbial diversity in nature. Appl. Environ. Microbiol. 62:2501-2507[Abstract].
33.	Page, R. D. M., and E. C. Holmes. 1998. Molecular evolution: a phylogenetic approach. Blackwell Science, Oxford, England.
34.	Park, J. K., T. Okamoto, Y. Yamasaki, K. Tanaka, T. Nakagawa, M. Kawamukai, and H. Matsuda. 1997. Molecular cloning, nucleotide sequencing, and regulation of the chiA gene encoding one of chitinases from Enterobacter sp. G-1. J. Ferment. Bioeng. 84:493-501[CrossRef].
35.	Roller, C., M. Wagner, R. Amann, W. Ludwig, and K. H. Schleifer. 1994. In situ probing of gram-positive bacteria with high DNA G+C content using 23S ribosomal-RNA-targeted oligonucleotides. Microbiology (Reading) 140:2849-2858[Abstract/Free Full Text].
36.	Sitrit, Y., C. E. Vorgias, I. Chet, and A. B. Oppenheim. 1995. Cloning and primary structure of the chiA gene from Aeromonas caviae. J. Bacteriol. 177:4187-4189[Abstract/Free Full Text].
37.	Suzuki, M. T., M. S. Rappé, Z. W. Haimberger, H. Winfield, N. Adair, J. Strobel, and S. J. Giovannoni. 1997. Bacterial diversity among small-subunit rRNA gene clones and cellular isolates from the same seawater sample. Appl. Environ. Microbiol. 63:983-989[Abstract].
38.	Svitil, A. L., and D. L. Kirchman. 1998. A chitin-binding domain in a marine bacterial chitinase and other microbial chitinases: implications for the ecology and evolution of 1,4-beta-glycanases. Microbiology (Reading) 144:1299-1308[Abstract/Free Full Text].
39.	Techkarnjanaruk, S., S. Pongpattanakitshote, and A. E. Goodman. 1997. Use of a promoterless lacZ gene insertion to investigate chitinase gene expression in the marine bacterium Pseudoalteromonas sp. strain S9. Appl. Environ. Microbiol. 63:2989-2996[Abstract].
40.	Tsujibo, H., H. Orikoshi, H. Tanno, K. Fujimoto, K. Miyamoto, C. Imada, Y. Okami, and Y. Inamori. 1993. Cloning, sequence, and expression of a chitinase gene from a marine bacterium, Altermonas sp. strain O-7. J. Bacteriol. 175:176-181[Abstract/Free Full Text].
41.	Zarda, B., D. Hahn, A. Chatzinotas, W. Schonhuber, A. Neef, R. I. Amann, and J. Zeyer. 1997. Analysis of bacterial community structure in bulk soil by in situ hybridization. Arch. Microbiol. 168:185-192[CrossRef].
42.	Zehr, J. P., and D. G. Capone. 1996. Problems and promises of assaying the genetic potential for nitrogen fixation in the marine environment. Microb. Ecol. 32:263-281[Medline].
43.	Ziemke, F., I. Brettar, and M. G. Höfle. 1997. Stability and diversity of the genetic structure of a Shewanella putrefaciens population in the water column of the central Baltic. Aquat. Microb. Ecol. 13:63-74.

Selected Chitinase Genes in Cultured and Uncultured Marine Bacteria in the - and -Subclasses of the Proteobacteria

Selected Chitinase Genes in Cultured and Uncultured Marine Bacteria in the $alpha$ - and $gamma$ -Subclasses of the Proteobacteria