Dm3 is one member of a large constitutively expressed family of nucleotide binding site-leucine-rich repeat encoding genes

The major cluster of resistance genes in lettuce cv. Diana contains approximately 32 nucleotide binding site-leucine-rich repeat encoding genes. Previous molecular dissection of this complex region had identified a large gene, RGC2B, as a candidate for encoding the downy mildew resistance gene, Dm3. This article describes genetic and transgenic complementation data that demonstrated RGC2B is necessary and sufficient to confer resistance with Dm3 specificity. Ethylmethanesulphonate was used to induce mutations to downy mildew susceptibility in cv. Diana (Dm1, Dm3, Dm7, and Dm8). Nineteen families were identified with a complete loss of resistance in one of the four resistance specificities. Sequencing revealed a variety of point mutations in RGC2B in the six dm3 mutants. Losses of resistance were due to single changes in amino acid sequence or a change in an intron splice site. These mutations did not cluster in any particular region of RGC2B. A full-length genomic copy of RGC2B was isolated from a lambdaphage library and introduced into two genotypes of lettuce. Transgenics expressing RGC2B exhibited resistance to all isolates expressing Avr3 from a wide range of geographical origins. In a wildtype Dm3-expressing genotype, many of the RGC2 family members are expressed at low levels throughout the plant.     

Receptor-like genes in the major resistance locus of lettuce are subject to divergent selection.

Disease resistance genes in plants are often found in complex multigene families. The largest known cluster of disease resistance specificities in lettuce contains the RGC2 family of genes. We compared the sequences of nine full-length genomic copies of RGC2 representing the diversity in the cluster to determine the structure of genes within this family and to examine the evolution of its members. The transcribed regions range from at least 7.0 to 13.1 kb, and the cDNAs contain deduced open reading frames of approximately 5. 5 kb. The predicted RGC2 proteins contain a nucleotide binding site and irregular leucine-rich repeats (LRRs) that are characteristic of resistance genes cloned from other species. Unique features of the RGC2 gene products include a bipartite LRR region with >40 repeats. At least eight members of this family are transcribed. The level of sequence diversity between family members varied in different regions of the gene. The ratio of nonsynonymous (Ka) to synonymous (Ks) nucleotide substitutions was lowest in the region encoding the nucleotide binding site, which is the presumed effector domain of the protein. The LRR-encoding region showed an alternating pattern of conservation and hypervariability. This alternating pattern of variation was also found in all comparisons within families of resistance genes cloned from other species. The Ka /Ks ratios indicate that diversifying selection has resulted in increased variation at these codons. The patterns of variation support the predicted structure of LRR regions with solvent-exposed hypervariable residues that are potentially involved in binding pathogen-derived ligands.     

Molecular analysis of irradiation-induced and spontaneous deletion mutants at a disease resistance locus inLactuca sativa

The major cluster of disease resistance genes in lettuce (Lactuca sativa) contains at least nine downy mildew resistance genes (Dm) spanning a genetic distance of 20 cM and a physical distance of at least 6 Mb. Nine molecular markers that were genetically tightly linked toDm3 were used to analyze nine independent deletion mutants and construct a map of the region surroundingDm3. This analysis identified a linear order of deletion breakpoints and markers along the chromosome. There was no evidence for chromosomal rearrangements associated with the deletions. The region is not highly recombinagenic and the deletion breakpoints provided greater genetic resolution than meiotic recombinants. The region contains a mixture of high- and low-copy-number sequences; no single-copy sequences were detected. Three markers hybridized to low-copy-number families of sequences that are duplicated predominantly close toDm3. This was not true for sequences related to the triose-phosphate isomerase gene; these had been shown previously to be linked toDm3, as well as to two independent clusters ofDm genes, and elsewhere in the genome. Two spontaneous mutants ofDm3 were identified; several markers flankingDm3 are absent in one of these two mutants. The stability of theDm3 region was also studied by analyzing the genotypes of diverse related cultivars. The 1.5 Mb region surroundingDm3 has remained stable through many generations of breeding with and without selection forDm3 activity.     

Molecular analysis of irradiation-induced and spontaneous deletion mutants at a disease resistance locus inLactuca sativa

The major cluster of disease resistance genes in lettuce (Lactuca sativa) contains at least nine downy mildew resistance genes (Dm) spanning a genetic distance of 20 cM and a physical distance of at least 6 Mb. Nine molecular markers that were genetically tightly linked toDm3 were used to analyze nine independent deletion mutants and construct a map of the region surroundingDm3. This analysis identified a linear order of deletion breakpoints and markers along the chromosome. There was no evidence for chromosomal rearrangements associated with the deletions. The region is not highly recombinagenic and the deletion breakpoints provided greater genetic resolution than meiotic recombinants. The region contains a mixture of high- and low-copy-number sequences; no single-copy sequences were detected. Three markers hybridized to low-copy-number families of sequences that are duplicated predominantly close toDm3. This was not true for sequences related to the triose-phosphate isomerase gene; these had been shown previously to be linked toDm3, as well as to two independent clusters ofDm genes, and elsewhere in the genome. Two spontaneous mutants ofDm3 were identified; several markers flankingDm3 are absent in one of these two mutants. The stability of theDm3 region was also studied by analyzing the genotypes of diverse related cultivars. The 1.5 Mb region surroundingDm3 has remained stable through many generations of breeding with and without selection forDm3 activity.     

Sources and genetic structure of a cluster of genes for resistance to three pathogens in lettuce

The second largest cluster of resistance genes in lettuce contains at least two downy mildew resistance specificities, Dm5/8 and Dm10, as well as Tu, providing resistance against turnip mosaic virus, and plr, a recessive gene conferring resistance against Plasmopara lactucae-radicis, a root infecting downy mildew. In the present paper four additional genetic markers have been added to this cluster, three RAPD markers and one RFLP marker, CL1795. CL1795 is a member of a multigene family related to triose phosphate isomerase; other members of this family map to the other two major clusters of resistance genes in lettuce. Seven RAPD markers in the region were converted into sequence characterized amplified regions (SCARs) and used in the further analysis of the region and the mapping of Dm10. Three different segregating populations were used to map the four resistance genes relative to molecular markers. There were no significant differences in gene order or rate of recombination between the three crosses. This cluster of resistance genes spans 6.4 cM, with Dm10 1.2 cM from Dm8. Marker analysis of 20 cultivars confirmed multiple origins for Dm5/8 specificity. Two different Lactuca serriola origins for the Du5/8 specificity had previously been described and originally designated as either Dm5 or Dm8. Some ancient cultivars also had the same specificity. Previously, due to lack of recombination in genetic analyses and the same resistance specificities, it was assumed that Dm5 and Dm8 were determined by the same gene. However, molecular marker analysis clearly identified genotypes characteristic of each source. Therefore, Dm5/8 specificity is either ancient and widespread in L. serriola and some L. sativa, or else has arisen on multiple occasions as alleles at the same locus or at linked loci.     

Recombination and spontaneous mutation at the major cluster of resistance genes in lettuce (Lactuca sativa)

Two sets of overlapping experiments were conducted to examine recombination and spontaneous mutation events within clusters of resistance genes in lettuce. Multiple generations were screened for recombinants using PCR-based markers flanking Dm3. The Dm3 region is not highly recombinagenic, exhibiting a recombination frequency 18-fold lower than the genome average. Recombinants were identified only rarely within the cluster of Dm3 homologs and no crossovers within genes were detected. Three populations were screened for spontaneous mutations in downy mildew resistance. Sixteen Dm mutants were identified corresponding to spontaneous mutation rates of 10(-3) to 10(-4) per generation for Dm1, Dm3, and Dm7. All mutants carried single locus, recessive mutations at the corresponding Dm locus. Eleven of the 12 Dm3 mutations were associated with large chromosome deletions. When recombination could be analyzed, deletion events were associated with exchange of flanking markers, consistent with unequal crossing over; however, although the number of Dm3 paralogs was changed, no novel chimeric genes were detected. One mutant was the result of a gene conversion event between Dm3 and a closely related homolog, generating a novel chimeric gene. In two families, spontaneous deletions were correlated with elevated levels of recombination. Therefore, the short-term evolution of the major cluster of resistance genes in lettuce involves several genetic mechanisms including unequal crossing over and gene conversion.     

Identification of restriction fragment length polymorphism and random amplified polymorphic DNA markers linked to downy mildew resistance genes in lettuce, using near-isogenic lines.

Near-isogenic lines were used to identify restriction fragment length polymorphism (RFLP) and random amplified polymorphic DNA (RAPD) markers linked to genes for resistance to downy mildew (Dm) in lettuce. Two pairs of near-isogenic lines that differed for Dm1 plus Dm3 and one pair of near-isogenic lines that differed for Dm11 were used as sources of DNA. Over 500 cDNAs and 212 arbitrary 10-mer oligonucleotide primers were screened for their ability to detect polymorphism between the near-isogenic lines. Four RFLP markers and four RAPD markers were identified as linked to the Dm1 and Dm3 region. Dm1 and Dm3 are members of a cluster of seven Dm genes. Marker CL922 was absolutely linked to Dm15 and Dm16, which are part of this cluster. Six RAPD markers were identified as linked to the Dm11 region. The use of RAPD markers allowed us to increase the density of markers in the two Dm regions in a short time. These regions were previously only sparsely populated with RFLP markers. The rapid screening and identification of tightly linked markers to the target genes demonstrated the potential of RAPD markers for saturating genetic maps.     

Evolution and genetic population structure of prickly lettuce (Lactuca serriola) and its RGC2 resistance gene cluster

Genetic structure and diversity of natural populations of prickly lettuce (Lactuca serriola) were studied using AFLP markers and then compared with the diversity of the RGC2 disease resistance gene cluster. Screening of 696 accessions from 41 populations using 319 AFLP markers showed that eastern Turkish and Armenian populations were the most diverse populations and might be located in the origin and center of diversity of L. serriola. Screening 709 accessions using the microsatellite MSATE6 that is located in the coding region of most RGC2 homologs detected 366 different haplotypes. Again, the eastern Turkish and Armenian populations had the highest diversities at the RGC2 cluster. The diversities at the RGC2 cluster in different populations were significantly correlated with their genomewide diversities. There was significant variation of copy number of RGC2 homologs in different populations, ranging from 12 to 22 copies per genome. The nucleotide diversities of two conserved lineages (type II) of RGC2 genes (K and L) were not correlated with diversities calculated using the MSATE6 or AFLP data. We hypothesize that the high genomewide diversity and diversity of the RGC2 cluster in eastern Turkish and Armenian populations resulted from high abiotic and biotic stresses in the regions of origin of L. serriola.     

Multiple genetic processes result in heterogeneous rates of evolution within the major cluster disease resistance genes in lettuce

Resistance Gene Candidate2 (RGC2) genes belong to a large, highly duplicated family of nucleotide binding site-leucine rich repeat (NBS-LRR) encoding disease resistance genes located at a single locus in lettuce (Lactuca sativa). To investigate the genetic events occurring during the evolution of this locus, approximately 1.5- to 2-kb 3' fragments of 126 RGC2 genes from seven genotypes were sequenced from three species of Lactuca, and 107 additional RGC2 sequences were obtained from 40 wild accessions of Lactuca spp. The copy number of RGC2 genes varied from 12 to 32 per genome in the seven genotypes studied extensively. LRR number varied from 40 to 47; most of this variation had resulted from 13 events duplicating two to five LRRs because of unequal crossing-over within or between RGC2 genes at one of two recombination hot spots. Two types of RGC2 genes (Type I and Type II) were initially distinguished based on the pattern of sequence identities between their 3' regions. The existence of two types of RGC2 genes was further supported by intron similarities, the frequency of sequence exchange, and their prevalence in natural populations. Type I genes are extensive chimeras caused by frequent sequence exchanges. Frequent sequence exchanges between Type I genes homogenized intron sequences, but not coding sequences, and obscured allelic/orthologous relationships. Sequencing of Type I genes from additional wild accessions confirmed the high frequency of sequence exchange and the presence of numerous chimeric RGC2 genes in nature. Unlike Type I genes, Type II genes exhibited infrequent sequence exchange between paralogous sequences. Type II genes from different genotype/species within the genus Lactuca showed obvious allelic/orthologous relationships. Trans-specific polymorphism was observed for different groups of orthologs, suggesting balancing selection. Unequal crossover, insertion/deletion, and point mutation events were distributed unequally through the gene. Different evolutionary forces have impacted different parts of the LRR.     

A Genetic Map of Lettuce (Lactuca sativa L.) with Restriction Fragment Length Polymorphism, Isozyme, Disease Resistance and Morphological Markers

A detailed linkage map of lettuce was constructed using 53 genetic markers including 41 restriction fragment length polymorphism (RFLP) loci, five downy mildew resistance genes, four isozyme loci and three morphological markers. The genetic markers were distributed into nine linkage groups and cover 404 cM which may be 25-30% of the lettuce genome. The majority (31 of 34) of the RFLP probes detected single segregating loci, although seven of these may have been homologous to further monomorphic loci. When several loci were detected by a single probe, the loci were generally linked, suggesting tandem duplications. One probe, however, detected loci in three linkage groups suggesting translocations. The five downy mildew resistance genes (Dm1, Dm3, Dm4, Dm5/8 and Dm13), segregating in the Calmar x Kordaat cross, represented each of the four resistance gene linkage groups. Dm5/8 is flanked by two cDNA loci, each located 10 cM away. These flanking markers will be used to study the source of variation in downy mildew genes and are also part our strategy to clone resistance genes.     

Diversity and evolution of a non-TIR-NBS sequence family that clusters to a chromosomal ’’hotspot” for disease resistance genes in soybean

In soybean, genes controlling resistance to numerous diseases have been shown to cluster to regions on several chromosomes. One such vital chromosomal region is on the soybean molecular linkage group (MLG) F flanked by the RFLP markers K644 and B212. Here, genes controlling resistance to bacterial blight, Phytophthora root rot, and several viral diseases, as well as QTLs conditioning resistance to corn earworm, root knot nematode, and white mold have been mapped. We have previously identified two classes (b and j) of disease resistance-related nucleotide binding site (NBS) sequences that localize to this cluster of genes. Using both cDNA and genomic analyses, we have studied one multi-gene family of sequences representing the previously reported class j NBS of soybean. This class of NBS resembles the RPS2-like NBS sequences. RPS2 and similar resistance genes are referred to as non-TIR because they do not encode motifs homologous to the Toll-Interleukin-1 region (TIR). By designing PCR primers that specifically target these non-TIR-NBS encoding sequences, we have amplified at least six class j sequence members from soybean. In addition, we have conducted genomic and cDNA library screenings to identify additional class j members. In all, we have characterized 12 class j NBS sequence members. These members have been mapped within a 2-cM region of the soybean F linkage group. We have also identified homoeologous chromosomal regions on linkage groups A2 and E that contain class j NBS sequences. A BLAST search of the GenBank database has shown that non-TIR NBS sequences are present across the legume family. We have compared these non-TIR sequences from other legumes with the soybean clones to assess the level of diversity within this class of disease resistance-related sequences.     

Mutants of Downy Mildew Resistance in Lactuca Sativa (Lettuce)

As part of our investigation of disease resistance in lettuce, we generated mutants that have lost resistance to Bremia lactucae, the casual fungus of downy mildew. Using a rapid and reliable screen, we identified 16 distinct mutants of Latuca sativa that have lost activity of one of four different downy mildew resistance genes (Dm). In all mutants, only a single Dm specificity was affected. Genetic analysis indicated that the lesions segregated as single, recessive mutations at the Dm loci. Dm3 was inactivated in nine of the mutants. One of five Dm1 mutants was selected from a population of untreated seeds and therefore carried a spontaneous mutation. All other Dm1, Dm3, Dm5/8 and Dm7 mutants were derived from γ- or fast neutron-irradiated seed. In two separate Dm1 mutants and in each of the eight Dm3 mutants analyzed, at least one closely linked molecular marker was absent. Also, high molecular weight genomic DNA fragments that hybridized to a tightly linked molecular marker in wild type were either missing entirely or were truncated in two of the Dm3 mutants, providing additional evidence that deletions had occurred in these mutants. Absence of mutations at loci epistatic to the Dm genes suggested that such loci were either members of multigene families, were critical for plant survival, or encoded components of duplicated pathways for resistance; alternatively, the genes determining downy mildew resistance might be limited to the Dm loci.     

Spatial patterns of diversity at the putative recognition domain of resistance gene candidates in wild bean populations

Leucine Rich Repeats (LRR) domains have been identified on most known plant resistance genes and appear to be involved in the specific recognition of pathogen strains. Here we explore the processes which may drive the evolution of this putative recognition domain. We developed AFLP markers specifically situated in the LRR domain of members of the PRLJ1 complex Resistance Gene Candidate (RGC) family identified in common bean (Phaseolus vulgaris). Diversity for these markers was assessed in ten wild populations of P. vulgaris and compared to locally co-occurring pathogen populations of Colletotrichum lindemuthianum. Nine PRLJ1 LRR specific markers were obtained. Marker sequences revealed that RGC diversity at PRLJ1 is similar to that at other complex R-loci. Wild bean populations showed contrasting levels of PRLJ1 LRR diversity and were all significantly differentiated. We could not detect an effect of local C. lindemuthianum population diversity on the spatial distribution of P. vulgaris PRLJ1 diversity. However, host populations have been previously assessed for neutral (RAPD) markers and for resistance phenotypes to six strains of C. lindemuthianum isolated from cultivated bean fields. A comparative analysis of PRLJ1 LRR diversity and host diversity for resistance phenotypes indicated that evolutionary processes related to the antagonistic C. lindemuthianum/P. vulgaris interaction are likely to have shaped molecular diversity of the putative recognition domains of the PRLJ1 RGC family members.     

Incomplete specific resistance to Bremia lactucae in lettuce

The complementary pair of dominant genes. Dm 7/1 and Dm 7/2 and the single dominant gene Dm 6 for specific resistance in Bremia lactucae in lettuce, condition incomplete resistance to non-virulent (incompatible) isolates of B. lactucae in both seedling and mature tissue. This incomplete resistance is characterised by a marked reduction in spotophore production compared with fully susceptible (compatible) race/cultivar combinations and by macroscopically visible hypersenstive cell necrosis. The incomplete resistance. In seedling the resistance conditioned by genes giving more complete resistance. In seedlings the resistance conditioned by genes Dm 7/1 and 7/2 was incomplete in outdoor 'crisp' lettuce genotypes and the resistance conditioned by gene Dm 6 was only completely expressed at 20°C.     

A cluster of expressed zinc finger protein genes in the pericentromeric region of human chromosome 10.

Three members of the human zinc finger Krüppel family, ZNF11/KOX2, ZNF22/KOX15, and ZNF25/KOX19, have been regionally localized to the pericentromeric region of chromosome 10 by in situ chromosomal hybridization and somatic cell hybrid analysis. ZNF25/KOX19 is located centromeric to a breakpoint in chromosome band 10q11.2 in the chromosome region 10p11.2-q11.2, whereas ZNF22/KOX15 maps distal to it in band 10q11.2. Sequences hybridizing to the KOX2 probe are found at two loci, ZNF11A and ZNF11B, that map proximal and distal to the 10q11.2 breakpoint, respectively. The two ZNF11 loci probably represent two related sequences in 10p11.2-q11.2. This cluster of ZNF/KOX genes is of particular interest since the loci for multiple endocrine neoplasia type 2A and 2B (MEN2A and MEN2B) syndromes have been assigned to this region by linkage analysis.     

The R1 resistance gene cluster contains three groups of independently evolving, type I R1 homologues and shows substantial structural variation among haplotypes of Solanum demissum

Cultivated and wild potatoes contain a major disease-resistance cluster on the short arm of chromosome V, including the R1 resistance (R) gene against potato late blight. To explore the functional and evolutionary significance of clustering in the generation of novel disease-resistance genes, we constructed three approximately 1 Mb physical maps in the R1 gene region, one for each of the three genomes (haplotypes) of allohexaploid Solanum demissum, the wild potato progenitor of the R1 locus. Totals of 691, 919 and 559 kb were sequenced for each haplotype, and three distinct resistance-gene families were identified, one homologous to the potato R1 gene and two others homologous to either the Prf or the Bs4 R-gene of tomato. The regions with R1 homologues are highly divergent among the three haplotypes, in contrast to the conserved flanking non-resistance gene regions. The R1 locus shows dramatic variation in overall length and R1 homologue number among the three haplotypes. Sequence comparisons of the R1 homologues show that they form three distinct clades in a distance tree. Frequent sequence exchanges were detected among R1 homologues within each clade, but not among those in different clades. These frequent sequence exchanges homogenized the intron sequences of homologues within each clade, but did not homogenize the coding sequences. Our results suggest that the R1 homologues represent three independent groups of fast-evolving type I resistance genes, characterized by chimeric structures resulting from frequent sequence exchanges among group members. Such genes were first identified among clustered RGC2 genes in lettuce, where they were distinguished from slow-evolving type II R-genes. Our findings at the R1 locus in S. demissum may indicate that a common or similar mechanism underlies the previously reported differentiation of type I and type II R-genes and the differentiation of type I R-genes into distinct groups, identified here.     

Localization of a gamma-glutamyl-transferase-related gene family on chromosome 22

A gene family encompassing a minimum of four genes or pseudogenes for gamma-glutamyl transferase (GGT; EC 2.3.2.2) is present on chromosome 22q11. We have previously isolated a cDNA related to GGT but clearly not belonging to its gene family. The chromosomal location of this related gene, GGTLA1, has been determined by both isotopic and fluorescence in situ hybridization to metaphase cells and by Southern blot analysis of somatic cell hybrid DNAs. We show that GGTLA1 is part of a distinct gene family, which has at least four members (GGTLA1, GGTLA2, GGTLA3, GGTLA4). At least two loci are located on chromosome 22 within band q11 and proximal to the chronic myelogenous leukemia (CML) breakpoint in BCR (breakpoint cluster region gene). At least one other member is located more distally between the breakpoints found in Ewings sarcoma and CML. Some of the GGT and GGTLA family members are located on NotI restriction enzyme fragments of a similar size. Combined results indicate that a segment of human chromosome 22q11 has undergone largescale amplification events relatively recently in evolution.     

First-generation SNP/InDel markers tagging loci for pathogen resistance in the potato genome

A panel of 17 tetraploid and 11 diploid potato genotypes was screened by comparative sequence analysis of polymerase chain reaction (PCR) products for single nucleotide polymorphisms (SNPs) and insertion-deletion polymorphisms (InDels), in regions of the potato genome where genes for qualitative and/or quantitative resistance to different pathogens have been localized. Most SNP and InDel markers were derived from bacterial artificial chromosome (BAC) insertions that contain sequences similar to the family of plant genes for pathogen resistance having nucleotide-binding-site and leucine-rich-repeat domains (NBS-LRR-type genes). Forty-four such NBS-LRR-type genes containing BAC-insertions were mapped to 14 loci, which tag most known resistance quantitative trait loci (QTL) in potato. Resistance QTL not linked to known resistance-gene-like (RGL) sequences were tagged with other markers. In total, 78 genomic DNA fragments with an overall length of 31 kb were comparatively sequenced in the panel of 28 genotypes. 1498 SNPs and 127 InDels were identified, which corresponded, on average, to one SNP every 21 base pairs and one InDel every 243 base pairs. The nucleotide diversity of the tetraploid genotypes (pi = 0.72 x 10(-3)) was lower when compared with diploid genotypes (pi = 2.31 x 10(-3)). RGL sequences showed higher nucleotide diversity when compared with other sequences, suggesting evolution by divergent selection. Information on sequences, sequence similarities, SNPs and InDels is provided in a database that can be queried via the Internet.     

Molecular detection of uncultured cyanobacteria and aminotransferase domains for cyanotoxin production in sediments of different Kenyan lakes

PCR-based denaturing gradient gel electrophoresis (DGGE) analysis of 16S rRNA gene fragments was used to identify the cyanobacterial phylotypes in sediments and plankton of saline–alkaline and freshwater lakes of Kenya. The detection of the aminotransferase domain located on modules mcyE and ndaF using specific molecular markers confirmed the presence of potential toxin-producing cyanobacteria. The eight nucleotide sequences obtained from DGGE bands were placed in three divergent cyanobacterial clusters. Five nucleotide sequences were close to members of the genera Anabaenopsis and Umezakia ( Nostocales ), two sequences fell in the cluster with Arthrospira sp. ( Oscillatoriales ) and one sequence was related to Chroococcidiopsis sp. ( Pleurocapsales ). The presence of the latter taxon was demonstrated de novo in the investigated lakes. All nine attained nucleotide sequences of the aminotransferase region belonged to the mcyE module. Five sequences of the aminotransferase domain were included in the cluster having the nucleotide sequence of Anabaena sp. but showed a separate lineage. Other four aminotransferases were placed in the cluster represented by nucleotide sequence of Microcystis aeruginosa . To our knowledge, this is the first report on molecular detection of cyanobacterial phylotypes in sediments of African lakes and aminotransferase domains for cyanotoxin production from sediment samples in general.