Detection, discrimination and discovery of a new Tobacco streak virus strain

Soybean plants that exhibited symptoms of virus infection were sampled from different counties of Oklahoma. These plants were tested serologically for 15 viruses known to infect soybean plants. Fifty-seven samples that exhibited typical virus-like symptoms did not test positive for any of the 15 viruses used in a dot-immunobinding assay (DIBA). Four samples were pooled and used for next generation sequencing using the 454-Roche protocol. Sequence and phylogenetic analysis of the sequences obtained revealed infection with a distinct strain of Tobacco streak virus (TSV). TSV was one of the 15 viruses initially tested for using DIBA and had tested negative. TSV belongs to the genus Ilarvirus and has been reported as a causal agent of bud blight in soybean crops in Brazil and the United States. Out of 10 reported primer pairs for TSV reverse transcription-polymerase chain reaction (RT-PCR), only two had the potential, based on sequence similarity, to amplify part of the genome of the distinct strain of TSV found in Oklahoma and only one was actually able to amplify the region. In this study, a new primer pair, specific to all known TSV and capable of amplifying the Oklahoma strain (TSV-OK), was designed from a highly conserved region of coat protein (CP) sequences and end-point PCR and quantitative RT-PCR detection methods were developed and their sensitivity assayed. This is the first report of specific primers designed from this highly conserved region in the CP of TSV for detection of TSV. Twenty-three of the 57 DIBA soybean samples that initially tested negative were retested with the new specific end-point PCR method and found positive for TSV infection.

Screening metagenomic data for viruses using the e-probe diagnostic nucleic acid assay

Next generation sequencing (NGS) is not used commonly in diagnostics, in part due to the large amount of time and computational power needed to identify the taxonomic origin of each sequence in a NGS data set. By using the unassembled NGS data sets as the target for searches, pathogen-specific sequences, termed e-probes, could be used as queries to enable detection of specific viruses or organisms in plant sample metagenomes. This method, designated e-probe diagnostic nucleic acid assay, first tested with mock sequence databases, was tested with NGS data sets generated from plants infected with a DNA (Bean golden yellow mosaic virus, BGYMV) or an RNA (Plum pox virus, PPV) virus. In addition, the ability to detect and differentiate among strains of a single virus species, PPV, was examined by using probe sets that were specific to strains. The use of probe sets for multiple viruses determined that one sample was dually infected with BGYMV and Bean golden mosaic virus.

Resistance of Spiroplasma citri Lines to the Virus SVTS2 Is Associated with Integration of Viral DNA Sequences into Host Chromosomal and Extrachromosomal DNA

Spiroplasmavirus SVTS2, isolated from Spiroplasma melliferum TS2, produces plaques when inoculated onto lawns of Spiroplasma citri M200H, a derivative of the type strain Maroc R8A2. S. citri strains MR2 and MR3, originally selected as colonies growing within plaques on a lawn of M200H inoculated with SVTS2, were resistant to SVTS2. Genomic DNA fingerprints and electrophoretic protein profiles of M200H, MR2, and MR3 were similar, but three proteins present in M200H were missing or significantly reduced in both resistant lines. None of these three polypeptides reacted with antiserum against S. citri membrane proteins, indicating that they probably are not surface-located virus receptors. Electroporation with SVTS2 DNA produced 1.5 x 10(sup5) transfectants per (mu)g of DNA in M200H but none in MR2 or MR3, suggesting that resistance may result from inhibition of viral replication. The digestion patterns of the extrachromosomal double-stranded (ds) DNA of these lines were similar. Three TaqI fragments of MR2 extrachromosomal DNA that were not present in M200H extrachromosomal DNA hybridized strongly to an SVTS2 probe, and two of these fragments plus an additional one hybridized with the MR3 extrachromosomal DNA, indicating that a fragment of SVTS2 DNA was present in the extrachromosomal ds DNA of MR2 and MR3 but not of M200H. When the restricted genomes of all three lines were probed with SVTS2 DNA, strong hybridization to two EcoRI fragments of chromosomal MR2 and MR3 DNA but not M200H DNA indicated that SVTS2 DNA had integrated into the genomes of MR2 and MR3 but not of M200H. When MR3 extrachromosomal ds DNA containing a 2.1-kb SVTS2 DNA fragment was transfected into M200H, the transformed spiroplasmas were resistant to SVTS2. These results suggest that SVTS2 DNA fragments, possibly integrated into the chromosomal or extrachromosomal DNA of a previously susceptible spiroplasma, may function as viral incompatibility elements, providing resistance to superinfection by SVTS2.

Genetic diversity of Spiroplasma citri strains from different regions, hosts, and isolation dates

Spiroplasma citri, a phloem-limited pathogen, causes citrus stubborn disease (CSD). Losses due to CSD in California orchards have grown over the past decade. To investigate the possibility of introduction or emergence of a new strain, a study of genetic diversity among S. citri strains from various locations was conducted using random amplified polymorphism DNA-polymerase chain reaction (RAPD-PCR) of 35 strains cultured from 1980 to 1993, and of 35 strains cultured from 2005 to 2006. Analysis using 20 primer pairs revealed considerable diversity among strains. However, no unique genetic signatures were associated with recently collected strains compared with those collected 15 to 28 years ago, and no geographically associated pattern was distinguishable. S. citri strains from carrot and daikon radish contain some unique DNA fragments, suggesting some host plant influence. Multiple strains from single trees also showed genetic diversity. Sequencing of five RAPD bands that differed among strains showed that diversity-related gene sequences include virus fragments, and fragments potentially encoding a membrane lipoprotein, a DNA modification enzyme, and a mobilization element. No differences in colony morphology were observed among the strains. The lack of correlation between PCR patterns and isolation date or collection site is inconsistent with the hypothesis that recent infections are due to the introduction or emergence of novel pathogen strains.

Plant pathogen forensics: capabilities, needs, and recommendations

A biological attack on U.S. crops, rangelands, or forests could reduce yield and quality, erode consumer confidence, affect economic health and the environment, and possibly impact human nutrition and international relations. Preparedness for a crop bioterror event requires a strong national security plan that includes steps for microbial forensics and criminal attribution. However, U.S. crop producers, consultants, and agricultural scientists have traditionally focused primarily on strategies for prevention and management of diseases introduced naturally or unintentionally rather than on responding appropriately to an intentional pathogen introduction. We assess currently available information, technologies, and resources that were developed originally to ensure plant health but also could be utilized for postintroduction plant pathogen forensics. Recommendations for prioritization of efforts and resource expenditures needed to enhance our plant pathogen forensics capabilities are presented.

Genomic comparison of plant pathogenic and nonpathogenic Serratia marcescens strains by suppressive subtractive hybridization

Cucurbit yellow vine disease (CYVD) is caused by disease-associated Serratia marcescens strains that have phenotypes significantly different from those of nonphytopathogenic strains. To identify the genetic differences responsible for pathogenicity-related phenotypes, we used a suppressive subtractive hybridization (SSH) strategy. S. marcescens strain Z01-A, isolated from CYVD-affected zucchini, was used as the tester, whereas rice endophytic S. marcescens strain R02-A (IRBG 502) was used as the driver. SSH revealed 48 sequences, ranging from 200 to 700 bp, that were present in Z01-A but absent in R02-A. Sequence analysis showed that a large proportion of these sequences resembled genes involved in synthesis of surface structures. By construction of a fosmid library, followed by colony hybridization, selection, and DNA sequencing, a phage gene cluster and a genome island containing a fimbrial-gene cluster were identified. Arrayed dot hybridization showed that the conservation of subtracted sequences among CYVD pathogenic and nonpathogenic S. marcescens strains varied. Thirty-four sequences were present only in pathogenic strains. Primers were designed based on one Z01-A-specific sequence, A79, and used in a multiplex PCR to discriminate between S. marcescens strains causing CYVD and those from other ecological niches.

Overwintering squash bugs harbor and transmit the causal agent of cucurbit yellow vine disease

Since 1988, cucurbit crops, particularly watermelon, cantaloupe, and squash, grown in Oklahoma and Texas have experienced devastating losses from cucurbit yellow vine disease (CYVD), caused by the phloem-limited bacterium Serratia marcescens Bizio. Squash bug, Anasa tristis (De Geer), is a putative vector of the pathogen. In 2000-2001, overwintering populations of squash bug collected from DeLeon, TX, were tested for their ability to harbor and transmit the bacterium. Individual squash bugs (n = 73) were caged serially for periods of up to 7 d on at least four squash seedlings. Two studies were conducted, one with insects collected in November 2000 placed on first true leaf-stage seedlings and the second with insects from an April 2001 collection, placed on 3-5 true leaf-stage squash. Controls consisted of squash seedlings caged without insects. Squash bug transmission rates of the pathogen in studies I and II were 20 and 7.5%, respectively. Overall, 11.0% of the squash bugs harbored and successfully transmitted the bacterium to squash seedlings. All control plants tested negative for S. marcescens and did not exhibit CYVD. Female squash bugs killed a significantly greater proportion of young first leaf-stage seedlings than males. Feeding on 3-5 leaf-stage squash resulted in no plant mortality regardless of squash bug gender. This study demonstrated that the squash bug harbors S. marcescens in its overwintering state. The squash bug-S. marcescens overwintering relationship reported herein greatly elevates the pest status of squash bug and places more importance on development of integrated strategies for reducing potential overwintering and emerging squash bug populations.

Identification, Phylogenetic Analysis, and Biological Characterization of Serratia marcescens Strains Causing Cucurbit Yellow Vine Disease

ABSTRACT A serious vine decline of cucurbits known as cucurbit yellow vine disease (CYVD) is caused by rod-shaped bacteria that colonize the phloem elements. Sequence analysis of a CYVD-specific polymerase chain reaction (PCR)-amplified 16S rDNA product showed the microbe to be a gamma-proteobacterium related to the genus Serratia. To identify and characterize the bacteria, one strain each from watermelon and zucchini and several noncucurbit-derived reference strains were subjected to sequence analysis and biological function assays. Taxonomic and phylogenetic placement was investigated by analysis of the groE and 16S rDNA regions, which were amplified by PCR and directly sequenced. For comparison, eight other bacterial strains identified by others as Serratia spp. also were sequenced. These sequences clearly identified the CYVD strains as Serratia marcescens. However, evaluation of metabolic and biochemical features revealed that cucurbit-derived strains of S. marcescens differ substantially from strains of the same species isolated from other environmental niches. Cucurbit strains formed a distinct cluster, separate from other strains, when their fatty acid methyl ester profiles were analyzed. In substrate utilization assays (BIOLOG, Vitek, and API 20E), the CYVD strains lacked a number of metabolic functions characteristic for S. marcescens, failing to catabolize 25 to 30 compounds that were utilized by S. marcescens reference strains. These biological differences may reflect gene loss or repression that occurred as the bacterium adapted to life as an intracellular parasite and plant pathogen.

Genotyping of Serratia marcescens Strains Associated with Cucurbit Yellow Vine Disease by Repetitive Elements-Based Polymerase Chain Reaction and DNA-DNA Hybridization

ABSTRACT The bacterium that causes cucurbit yellow vine disease (CYVD) has been placed in the species Serratia marcescens based on 16S rDNA and groE sequence analysis. However, phenotypic comparison of the organism with S. marcescens strains isolated from a variety of ecological niches showed significant heterogeneity. In this study, we compared the genomic DNA of S. marcescens strains from different niches as well as type strains of other Serratia spp. through repetitive elements-based polymerase chain reaction (rep-PCR) and DNA-DNA hybridization. With the former, CYVD strains showed identical banding patterns despite the fact that they were from different cucurbit hosts, geographic locations, and years of isolation. In the phylogenetic trees generated from rep-PCR banding patterns, CYVD strains clearly were differentiated from other strains but formed a loosely related group with S. marcescens strains from other niches. The homogeneity of CYVD strains was supported further by the DNA relatedness study, in that labeled DNA from the cantaloupe isolate, C01-A, showed an average relative binding ratio (RBR) of 99%, and 0.33% divergence to other CYVD strains. Used as a representative strain of CYVD, the labeled C01-A had a RBR of 76%, and a 4.5% divergence to the S. marcescens type strain. These data confirm the previous placement of CYVD strains in S. marcescens. Our investigations, including rep-PCR, DNA-DNA hybridization, and previous phenotyping experiments, have demonstrated that CYVD-associated strains of S. marcescens cluster together in a group significantly different from other strains of the species.

Serratia marcescens, a Phloem-Colonizing, Squash Bug -Transmitted Bacterium: Causal Agent of Cucurbit Yellow Vine Disease

Cucurbit yellow vine disease (CYVD), which can inflict heavy losses to watermelon, pumpkin, cantaloupe, and squash in U.S. production areas from the midwest to northeastern states, causes phloem discoloration, foliar yellowing, wilting, and plant decline. Bacteria were cultured from the phloem of crown sections of symptomatic plants of Citrullus lanatas and Cucurbita pepo. Those bacteria testing positive in CYVD-specific polymerase chain reaction (PCR) were all gram negative and appeared morphologically identical, producing creamy white, smooth, entire, convex colonies on Luria-Bertani or nutrient agar. Characterized cucurbit-derived strains of Serratia marcescens were introduced into greenhouse-grown squash plants by puncture inoculation and into field-grown squash plants by enclosure with S. marcescens-fed squash bugs, Anasa tristis. Up to 60% of the bacteria-inoculated plants in the greenhouse and up to 17% of field plants caged with inoculative squash bugs developed phloem discoloration and tested positive for S. marcescens by CYVD-specific PCR. None of the controls developed phloem discoloration or tested positive by PCR. Of the diseased field plants, 12% (2 of 35) also yellowed, wilted, and collapsed, exhibiting full symptom development of CYVD. However, neither plant collapse nor decline was observed in the greenhouse-grown, puncture-inoculated plants. The morphology, growth habit, and PCR reaction of bacteria cultured from crown tissue of a subset of plants in each experimental group were indistinguishable from those of the inoculum bacteria. Evidence presented from our studies confirms that the squash bug can transmit S. marcescens, the CYVD causal bacterium. The S. marcescens-A. tristis relationship described here is the first instance in which the squash bug has been identified as a vector of a plant pathogen. Our experiments represent a completion of the steps of Koch's postulates, demonstrating that S. marcescens is the causal agent of CYVD and that the squash bug, A. tristis, is a vector of the pathogen.

Isolate-specific synergy in disease symptoms between cauliflower mosaic and turnip vein-clearing viruses

Simultaneous infection of a plant by two viruses can cause more severe disease than is caused by infection with either virus alone. Such synergy may be due to effects on the replication of one virus by the second virus or to other causes. The tobamovirus turnip vein-clearing virus (TVCV), itself causing almost imperceptible symptoms in infected turnips, exacerbated symptoms of infection of turnip by the Cabbage S isolate of the caulimovirus cauliflower mosaic virus (CaMV). The synergy in symptom production was most evident in a reduced size of leaves, providing an objective measure of synergy. In contrast, synergy did not occur when the CM4-184 isolate of CaMV was used in combination with TVCV. Both isolates of CaMV increased the level of TVCV accumulated in leaves. TVCV did not increase the level of the Cabbage S CaMV isolate. The use of Cabbage S-CM4-184 chimeras revealed that a region critical for isolate synergy in stunting was within the coat protein gene and/or the 5' one third of the reverse transcriptase gene. We conclude that the disease symptom synergy between TVCV and Cabbage S CaMV is not caused by altered levels of accumulation of the viruses, but instead reflects subtle genetic interactions mapping to the ORF IV-ORF V region of CaMV DNA.

Characterization of Spiroplasma citri adhesion related protein SARP1, which contains a domain of a novel family designated sarpin

Transmission of the plant pathogen Spiroplasma citri by its leafhopper vector, Circulifer tenellus, involves adherence to and invasion of insect host cells. The S. citri adhesion related protein P89 (SARP1) was purified by immunoprecipitation using anti-SARP1 monoclonal antibodies. The protein's N-terminal amino acid sequence was determined and used to design a degenerate oligonucleotide. The labeled oligonucleotide hybridized to a 3.5 kb MboI fragment from S. citri DNA, which was then cloned and sequenced. Additionally, a 1.9 kb RsaI fragment of S. citri DNA, partially overlapping the MboI fragment, was isolated and characterized. Sequence analysis of the two clones revealed four open reading frames. ORF1 (675 bp) encodes the C-terminal part of a Soj-like protein. ORFs 1 and 2 were separated from ORFs 3 and 4 by a putative transcription termination site, indicated by a hairpin structure. ORF3 encodes an amphiphilic 798 amino acid long protein with a cleavable signal peptide and a predicted transmembrane helix near the C-terminus. The mature protein of 85.96 kDa has a calculated pI value of 5.5 and has an N-terminal amino acid sequence consistent with that determined from the purified SARP1. At the N-terminus of this protein is a region consisting of six repeats, each 39-42 amino acids, a motif belonging to a previously unrecognized family of repeats found in a variety of bacterial proteins. The taxonomically spotty presence of this 'sarpin' domain and the relationship of the repeats to each other suggests a convergent evolution in multiple lineages.

Common elements of spiroplasma plectroviruses revealed by nucleotide sequence of SVTS2

DNA of SpV1-like spiroplasma plectroviruses (rods with single-stranded circular DNA) is scattered in the genome of the phytopathogen Spiroplasma citri and has significant consequences for evolution of the S. citri genome. We determined the complete nucleotide sequence of SVTS2, a SpV1-like virus of S. melliferum, a honeybee pathogen, to ascertain, by comparison with S. citri SpV1 viruses (GenBank U28974 and X51344), the defining features of this important group. The 6,824 nt DNA contains nine ORFs homologous to ORFs of S. citri SpV1 viruses and five ORFs unique to SVTS2. The predicted amino acid sequences of the homologous ORFs were 17-38% identical to those of their S. citri counterparts. The SVTS2 predicted ORF 1 product (Mr 47,031) was considerably smaller than those of known S. citri SpV1 viruses. Also, in contrast to those viruses, SVTS2 lacked an ORF with recognizable similarity to a transposase. ORF 2 of all three viruses had a homologue among the products of genes of MVL-1, a virus of Acholeplasma laidlawii, another plectrovirus. The results suggest that, at most, only slightly more than half of SpV1 genomes consists of genes shared by all spiroplasma viruses of the group.

The '30K' superfamily of viral movement proteins

Relationships among the amino acid sequences of viral movement proteins related to the 30 kDa ('30K') movement protein of tobacco mosaic virus - the 30K superfamily - were explored. Sequences were grouped into 18 families. A comparison of secondary structure predictions for each family revealed a common predicted core structure flanked by variable N- and C-terminal domains. The core consisted of a series of beta-elements flanked by an alpha-helix on each end. Consensus sequences for each of the families were generated and aligned with one another. From this alignment an overall secondary structure prediction was generated and a consensus sequence that can recognize each family in database searches was obtained. The analysis led to criteria that were used to evaluate other virus-encoded proteins for possible membership of the 30K superfamily. A rhabdoviral and a tenuiviral protein were identified as 30K superfamily members, as were plant-encoded phloem proteins. Parsimony analysis grouped tubule-forming movement proteins separate from others. Establishment of the alignment of residues of diverse families facilitates comparison of mutagenesis experiments done on different movement proteins and should serve as a guide for further such experiments.

Mechanisms of spiroplasma genome variation associated with SpV1-like viral DNA inferred from sequence comparisons

Genomes of Spiroplasma citri strains have rearranged frequently during their evolution, partly due to multiple integrated sequences of spiroplasma viruses. To understand better the role of viral sequences in genome evolution, we examined available nucleotide sequences of viruslike elements in the S. citri chromosome. Comparison of integrated and nonintegrated sequences of spiroplasma virus SpV1-C74 DNA suggested that it is an encapsidated form of the circular transposition intermediate belonging to an insertion sequence (IS3) family member. One SpV1-C74 viral DNA fragment was identified as interrupting the remains of a DNA adenine modification methylase gene. A viral DNA insertion of SpV1-R8A2 B DNA had hallmarks of having suffered an internal deletion by a site-specific recombination system. Homologous recombination likely was responsible for several deletions within viral DNA. A homologous recombination event was inferred between part of a viral DNA insertion and a similar chromosomal sequence. Dispersed sequences from SpV1-like C4 open reading frames (ORFs) were identified as involved in a complex deletion-inversion event. Thus, SpV1-like sequences likely have altered spiroplasma genomes by inserting within active genes, destroying their function, by providing targets for site-specific recombination, by mediating deletions of sequences adjacent to their integration sites, and by providing targets for homologous recombination, leading to inversions.

Yellow Vine of Watermelon and Pumpkin in Tennesse

Yellow vine (YV) is a recently recognized decline of cucurbits expressed as plant yellowing, phloem discoloration, and death of vines as fruit approach maturity. In severely affected fields, YV incidence can range from 50 to 100% with similar yield loss. The disease has been associated with a phloem-limited, walled bacterium belonging to the gamma-3-proteobacteria (1), for which specific polymerase chain reaction (PCR) primers have been developed and used in diagnosis (2). First observed in 1988 in Oklahoma and Texas squash and pumpkin, YV was not detected in watermelon and cantaloupe until 1991. The disease has never been detected in cucumber. Efforts to date have been unsuccessful in transmitting the disease with dodder, grafting, or selected insects. Initially, the geographic range of the disease appeared to be generally confined to central and northeastern Oklahoma and north central Texas, an area known as the Cross Timbers Region. In 1997 to 1998, YV was diagnosed in commercial fields of watermelon and muskmelon from east Texas (Post Oak Savannah) and all cucurbit-growing areas of Oklahoma. In late summer 1998, symptoms similar to those of YV were observed in one watermelon (Hardeman County) and three pumpkin (Rhea and Morgan counties) fields in Tennessee where the leaves turned yellow and chlorotic and affected plants exhibited phloem discoloration. Estimated incidence of YV ranged from less than 1 to 20% of the plants in affected fields. PCR, with the YV-specific primers (2), amplified a band of the expected size (409 bp) from all watermelon and pumpkin plants exhibiting phloem discoloration. In contrast, no bands were amplified from asymptomatic (no phloem discoloration) watermelon or pumpkin. The nucleotide sequence of the DNA fragment amplified from a Tennessee watermelon and pumpkin plant was identical to that of the YV bacterium. The occurrence of YV outside of the Cross Timbers Region, and in a location as distant as Tennessee, suggests that the disease may be much more widespread than previously recognized. Diagnosis and monitoring of YV in all cucurbit-growing areas is critical for determining the geographic distribution and losses caused by this emerging disease. References: (1) F. J. Avila et al. Phytopathology 88:428, 1998. (2) U. Melcher et al. (Abstr.) Phytopathology. 89(suppl.):S95, 1999.

Limitations to tobacco mosaic virus infection of turnip

Turnip vein-clearing virus (TVCV) and tobacco mosaic virus (TMV) represent subgroups of tobamoviruses infecting cruciferous and solanaceous plants, respectively. To identify adaptations that may have been necessary in the evolution of the TVCV subgroup from a TMV-like ancestor, the infection of turnip plants by TMV and by chimeras between TMV and TVCV was explored. TMV accumulated at spatially limited sites on inoculated turnip leaves as determined by leaf skeleton hybridization. A plasmid DNA containing a complete TVCV cDNA, when transcribed in vitro, produced RNA that was infectious to tobacco and turnip plants. TVCV-TMV chimeric genomes with junctions within coding regions were not infectious to tobacco, though the movement protein (MP) chimera was infectious to tobacco with a TMV MP transgene. Reciprocal chimeras with junctions between genes were infectious to tobacco. TVCV with a TMV MP gene infected turnips. The other tested chimeras were not detected in non-inoculated leaves, but were found in the inoculated leaves. Thus, the TMV MP is not responsible for the limitation of TMV spread in turnips.

The phytopathogenic mollicute-insect vector interface: a closer look

ABSTRACT Spiroplasma citri, transmitted by phloem-feeding leafhoppers, moves from the gut lumen through the gut wall, hemolymph, and salivary glands and multiplies in insect tissues. Nontransmissible lines were deficient in their ability to cross these barriers. Molecular analysis revealed extensive chromosomal rearrangements between the transmissible and nontransmissible spiroplasma lines including a large chromosomal inversion and deletions of about 10 kb at each inversion border. One open reading frame of the deleted region, cloned from the transmissible strain BR3-3X, encodes an integral membrane protein of 58 kDa that shares limited sequence similarity with major adhesin proteins of two zoopathogenic mycoplasmas. Adhesion of spiroplasmas to cultured leafhopper cells was inhibited by proteases, suggesting that adherence to host cells is mediated by spiroplasma membrane protein(s). A hypothetical model for insect transmission of phytopathogenic mollicutes is presented.

Polymerase chain reaction detection and phylogenetic characterization of an agent associated with yellow vine disease of cucurbits

ABSTRACT Diagnosis of yellow vine disease (YVD) in cucurbits, an important disease in the south-central United States, relies on external symptom appearance, phloem discoloration, and the presence of bacterium-like organisms (BLOs) in phloem. Polymerase chain reaction (PCR) amplification of BLO nucleotide sequences was explored as a means to improve diagnostic techniques. PCR, using a primer pair based on sequences of the citrus-greening BLO, amplified a 0.15-kilobase (kb) fragment from the DNA of symptomatic plants, but not from that of asymptomatic plants. Its nucleotide sequence suggested that the DNA amplified was of pro-karyotic origin. A primer pair, designed to amplify nonspecific prokaryotic 16S rDNA, amplified a 1.5-kb DNA fragment in both the symptomatic and asymptomatic plants. The 1.5-kb fragment from the asymptomatic plants corresponded to chloroplast 16S rDNA, and the band from the symptomatic plants was composed of 16S rDNAs from both chloroplasts and a prokaryote. The nucleotide sequence of the prokaryotic DNA was determined and used to design three primers (YV1, YV2, and YV3). Fragments of 0.64 and 1.43 kb were amplified with primers YV1-YV2 and primers YV1-YV3, respectively, from symptomatic plants. Neither primer set yielded fragments from asymptomatic plants, unrelated bacteria, or selected soilborne fungal pathogens of cucurbits. Phylogenetic analysis indicated that the prokaryote is a gamma-3 proteobacterium. The consistent association of the 0.64- and 1.43-kb fragments with symptomatic plants suggests that the gamma-3 proteobacterium may be the causal agent of YVD of cantaloupe, squash, and watermelon.

Molecular characterization of a gene encoding a membrane protein of Spiroplasma citri

A 9.6-kb genomic DNA segment, previously cloned from the phytopathogen Spiroplasma citri BR3-3X [Fletcher et al. (1981) Phytopathology 71, 1073-1080], contained several open reading frames including one encoding a 58-kDa protein. In this work, the transcription initiation site of the P58 mRNA was mapped and part of the gene was expressed in Escherichia coli as a fusion protein. A synthetic peptide, whose sequence is included in the fusion protein, was produced. Antibodies against both the fusion protein and the peptide reacted with a 60-kDa protein in a S. citri total protein extract. Hydrophobicity characteristics of this protein and its fractionation into the detergent phase indicated that P58, which shares limited sequence similarity with the adhesin of Mycoplasma hominis and the attachment protein of M. genitalium, is an integral membrane protein.

Tobamovirus evolution: gene overlaps, recombination, and taxonomic implications

Tobamoviruses, mostly isolated from solanaceous plants, may represent ancient virus lineages that have codiverged with their hosts. Recently completed nucleotide sequences of six nonsolanaceous tobamoviruses allowed assessment of the codivergence hypothesis and support a third subgroup within tobamoviruses. The genomic sequences of 12 tobamoviruses and the partial sequences of 11 others have been analyzed. Comparisons of the predicted protein sequences revealed three clusters of tobamoviruses, corresponding to those infecting solanaceous species (subgroup 1), those infecting cucurbits and legumes (subgroup 2), and those infecting crucifers. The orchid-infecting odontoglossum ringspot tobamovirus was associated with subgroup 1 genomes by its coat and movement protein sequences, but with the crucifer-pathogenic tobamoviruses by the remainder of its genome, suggesting that it is the progeny of a recombinant. For four of five genomic regions, subgroup 1 and 3 genomes were equidistant from a subgroup 2 genome chosen for comparison, suggesting uniform rates of evolution. A phylogenetic tree of plant families based on the tobamoviruses they harbor was congruent with that based on rubisco sequences but had a different root, suggesting that codivergence was tempered by rare events of viruses of one family colonizing another family. The proposed subgroup 3 viruses probably have an origin of virion assembly in the movement protein gene, a large (25-codon) overlap of movement and coat protein open reading frames, and a comparably shorter genome. Codon-position-dependent base compositions and codon prevalences suggested that the coat protein frame of the overlap region was ancestral. Bootstrapped parsimony analysis of the nucleotides in the overlap region and of the sequences translated from the -1 frame (the subgroup 3 movement protein frame) of this region produced trees inconsistent with those deduced from other regions. The results are consistent with a model in which a no or short overlap organization was ancestral. Despite encoding of subgroup 2 and 3 movement protein C-termini by nonhomologous nucleotides, weak similarities between their amino acid sequences suggested convergent sequence evolution.

Extensive chromosome aberrations in Spiroplasma citri Strain BR3

Genetic variations in the plant pathogen, Spiroplasma citri strain BR3, were characterized through physical genome mapping of the original isolate, BR3-3X, and two derivatives, BR3-T and BR3-G, obtained after several years of different maintenance conditions. BR3-T was transmitted from plant to plant via its natural insect vector, the leafhopper Circulifer tenellus, while BR3-G was maintained only in plants by periodic grafting and has lost its ability to be insect transmitted. By pulsed field gel electrophoresis (PFGE) analysis and DNA hybridization, extensive changes in chromosomal DNA restriction patterns relative to the parent, BR3-3X, were observed in both BR3-T and BR3-G, each of which also had a larger genome size than the parent line. Genetic organization was relatively conserved between BR3-T and BR3-3X. In contrast, a large chromosomal inversion and deletions of approximately 10 kb near each of the inversion borders were observed in BR3-G. One of the deletions, which included several possibly functional genes, was closely linked to a SpV1-related transposase gene. The locations of the deletion borders were also determined. The results of this study demonstrated remarkable genome instability of spiroplasmas.

Completion of a cDNA sequence from a tobamovirus pathogenic to crucifers

Turnip vein-clearing virus (TVCV) is a tobamovirus related to ribgrass mosaic virus. We report the nucleotide (nt) sequences of the 5'-untranslated region (UTR) and the 3'-half of the TVCV genome (the 3' region of the 182-kDa protein-encoding gene, as well as the movement protein and coat protein genes and the 3'-UTR). The determination completes the nt sequence of the cDNA of TVCV.

Phylogenetic relationships reveal recombination among isolates of cauliflower mosaic virus

Isolates of cauliflower mosaic virus (CaMV) differ in host range and symptomatology. Knowledge of their sequence relationships should assist in identifying nucleotide sequences responsible for isolate-specific characters. Complete nucleotide sequences of the DNAs of eight isolates of CaMV were aligned and the aligned sequences were used to analyze phylogenetic relationships by maximum likelihood, bootstrapped parsimony, and distance methods. Isolates found in North America clustered separately from those isolated from other parts of the world. Additional isolates, for which partial sequences were available, were incorporated into phylogenetic analysis of the sequences of genome segments corresponding to individual protein coding regions or the large intergenic region of CaMV DNA. The analysis revealed several instances where the position of an isolate on a tree for one coding region did not agree with the position of the isolate on the tree for the complete genome or with its position on trees for other coding regions. Examination of the distribution of shared residue types of phylogenetically informative positions in anomalous regions suggested that most of the anomalies were due to recombination events during the evolution of the isolates. Application of an algorithm that searches for segments of significant length that are identical between pairs of isolates or contain a significantly high concentration of polymorphisms suggested two additional recombination events between progenitors of the isolates studied and an event between the XinJing isolate and a CaMV not represented in the data set. An earlier phylogenetic origin for CaMV than for carnation etched ring virus, the caulimovirus used as outgroup in these analyses, was deduced from the position of the outgroup with North American isolates in some trees, but with non-North American isolates in other trees.

Electron microscopic and molecular characterization of turnip vein-clearing virus

We recently isolated turnip vein-clearing virus (TVCV), a tobamovirus which causes vein clearing in Brassica rapa (turnip) and a mosaic in Nicotiana tabacum (tobacco). We present an electron microscopic and molecular characterization of TVCV. Viral particles from lower epidermis peel contained rod-shaped viral particles, typical of tobamoviruses. Viral RNA extracted from infected turnip leaves was used as template for cDNA synthesis prior to cloning in a plasmid vector. Inserts of selected cDNA clones were sequenced to obtain the nucleotide sequence of the 126 K replicase component. The nucleotide and predicted amino acid sequences were 56 to 59% identical to those of most other sequenced tobamoviruses. The least related sequence, that of cucumber green mottle mosaic virus, was more related to the TVCV lineage than it was to those of the other sequenced tobamoviruses. UV spectroscopy suggested a tryptophan content characteristic of the ribgrass mosaic virus (RMV) group. Fragmentation of the TVCV coat protein by cyanogen bromide treatment produced a profile of fragments indistinguishable from those generated from the coat protein of RMV. Thus, while symptoms of TVCV infection on Nicotiana tabacum cv. Samsun and Nicotiana clevelandii differ from those reported for RMV, TVCV appears to be closely related to RMV.

Patterns of nucleotide sequence variation among cauliflower mosaic virus isolates

A consensus nucleotide sequence of the DNA of nine isolates of cauliflower mosaic virus (CaMV) was used to examine variation of nucleotide sequence in CaMV. Variability in coding regions was lowest in open reading frames (ORFs) 1, 2, 3 and 5 and higher in ORFs 4 and 6. Silent substitutions were not uniformly distributed among the ORFs. The large intergenic region was also variable, particularly in loops and bulges of a predicted secondary structure for this region of the 35S RNA transcript. A profile of frequencies of the substitution of consensus nucleotides with other nucleotides revealed a deficit of A to G transitions and an excess of transversions involving A. Most insertions/deletions could be accounted for by template misalignment during replication. The results suggest that the major source of variation in CaMV DNA sequences is associated with replication by reverse transcription.

Coat protein of cauliflower mosaic virus binds to ssDNA

Alkali-denatured cauliflower mosaic virus (CaMV) virions incorporated ssDNA, added exogenously, into multimolecular complexes during dialysis against a neutral buffer. CaMV coat protein binding to tracer DNA, assessed by gel electrophoresis and autoradiography, was highly cooperative as judged by the absence of intermediate-sized complexes. The incorporation of labelled BglII fragments of a plasmid containing CaMV DNA into complexes was prevented by the presence of 0.16 g/l unlabelled calf thymus DNA. Lower concentrations of competitor DNA allowed binding of some BglII fragments although preventing the binding of others. The self-annealing poly(dI-dC) was much less efficient than calf thymus DNA in preventing the incorporation of fragments into complexes, suggesting a binding preference for ss- over dsDNA. In addition, dsDNA, minimally cross-linked to prevent strand separation, was bound only weakly. End-labelled ssDNA fragments in complexes were partially protected against DNase I. The nucleic acid-binding activity of CaMV coat protein may be responsible for the organization of replication complexes, the precursors to virion particles.

HIV-1 proteinase as structural model of intercellular transport proteins of plant viruses

Intracellular movement of viral infections of plants requires a virus-encoded protein. Alignment of amino acid sequences of central conserved regions of such proteins produced a sequence profile that resembled that of lentiviral proteinases. The known three-dimensional structure of the proteinase encoded by the human immunodeficiency virus-1 (HIV-1) may serve as a model for the three-dimensional structure of the central region of the plant viral proteins. Secondary structures predicted for the plant viral proteins from their amino acid sequences correlate well with those predicted from a proteinase model. In addition, the positions of temperature-sensitive and resistance-breaking mutations in the intercellular transport protein of tobacco mosaic virus are consistent with a structural similarity between the plant viral proteins and the lentiviral proteinases. In a suggested model, the dimeric proteinase-similar domain serves as tether for the attachment of N- and C-terminal domains. The C-terminal domain may be an RNA-binding domain. The similarity was used to assign intercellular transport function to a previously unidentified coding region of the genomes of bacilliform DNA viruses.

A method for the isolation of nuclear DNA from cotton (Gossypium) leaves

Cotton leaves contain high levels of polyphenolic compounds that irreversibly interact with proteins and nucleic acids during DNA isolation. A procedure to isolate nuclear DNA from cotton (Gossypium hirsutum L.) has been developed. The method is based on the rapid initial isolation of nuclei in a glucose medium designed to stabilize nuclear structure and composition while preventing covalent interactions with polyphenolics. The resulting DNA is high in yield and purity and is suitable for Southern-blot hybridization analysis and restriction fragment length polymorphism analysis.

The complete nucleotide sequence of cauliflower mosaic virus isolate BBC

We report the complete nucleotide sequence of BBC, a new and unique isolate of cauliflower mosaic virus (CaMV). The organization of the BBC genome agrees with that of previously sequenced CaMV isolates.

In planta deletion of DNA inserts from the large intergenic region of cauliflower mosaic virus DNA

RNA splicing and copy-choice recombination lead to deletions in the DNA of cauliflower mosaic virus (CaMV). To assess the relative importance of these mechanisms of nucleotide sequence change, free of constraints imposed by the "relay race" mode of translation of CaMV RNA, we examined the stability of inserts in the large intergenic region. The insertions had, in various combinations, splicing signals and directly repeated sequences that could facilitate deletion. Most modified DNAs were infectious. Viral DNA recovered from infected plants was analyzed by restriction and, in some cases, cloned for nucleotide sequencing to determine deletion endpoints. Deletions from a DNA containing introduced splicing signals occurred primarily at direct repeats, although deletion apparently by splicing was also detected. Both types of deletion were also observed with insertions containing a 5' splice donor but no known functional 3' splice acceptor. One DNA, whose insertion lacked splicing signals and short repeated sequences, was stable in one of two plants infected. Total insert deletions were bounded by repeats or pseudorepeats, while partial insert deletions apparently occurred by splicing. The results suggest that the two mechanisms for deletion of nucleotides are equally important in the evolution of caulimoviral nucleotide sequences.

Diverse mechanisms of plant resistance to cauliflower mosaic virus revealed by leaf skeleton hybridization

Plants not hosts for cauliflower mosaic virus (CaMV) may prevent systemic CaMV infection by interfering with dissemination of infection through the plant or by preventing viral replication and maturation. Leaf skeleton hybridization allows distinction between these two barriers. The technique assesses the spatial distribution of CaMV in an inoculated leaf by hybridization of a skeleton of the leaf with a CaMV DNA probe. Leaves or leaflets of soybean, cucumber, peanut, tomato, lettuce, spinach, pepper, onion, wheat, maize and barley, inoculated with CaMV DNA or CaMV virions were processed for leaf skeleton hybridization either immediately after inoculation or two weeks thereafter. Autoradiographic images of soybean and cucumber skeletons had many dark spots suggesting that CaMV DNA replication and local spread had occurred. Images of onion leaf skeletons prepared two weeks after inoculation with CaMV DNA had fewer spots. To test whether these spots resulted from CaMV replication, DNA was extracted from inoculated onion leaves and analyzed by electrophoresis, blotting and hybridization. Molecules recovered two weeks after inoculation resembled those inoculated, indicating absence of replication. For the other species, we found no evidence of local spread of CaMV infections. Thus, many plant species resist systemic CaMV infection by preventing replication or local spread of CaMV, while others solely prevent systemic movement of infection.

Recombination sites in cauliflower mosaic virus DNAs: implications for mechanisms of recombination

Pairs of mutant cauliflower mosaic virus (CaMV) DNAs readily recombine in plants. Five plasmid clones of CaMV DNAs resulting from infection of turnips with pairs of mutant DNAs from DNAs resulting from infection of turnips with pairs of mutant DNAs from different isolates were obtained. Restriction analysis and nucleotide sequencing identified deletions in two cloned recombinants, VR1249 and VR244B. The sequence missing in the former was consistent with its deletion by splicing of an RNA intermediate. These DNAs were not infectious in turnips. VR1243, VR244A, and VR246 induced in turnips disease symptoms that were mixtures of those produced by the parental isolates. Junctions between sequences of the parental isolates were identified by restriction fragment analysis. Three cloned chimeras resulted from multiple recombination events. Nucleotide sequencing identified more precisely the junctions in the five cloned chimeras and in three chimeras previously characterized. Consistent with a model in which reverse transcription plays a major role in generating recombinants, six chimeras had junctions at or near the site for initiation of DNA(-) strand synthesis, three had junctions near the initiation site of 35 S RNA transcription, and one junction was found near the initiation site of 19 S mRNA transcription. Junctions were also found in regions not bearing any obvious relation to DNA (-) strand synthesis by reverse transcription, suggesting that recombination of double-stranded DNAs may also generate CaMV DNA recombinants.

Similarities between putative transport proteins of plant viruses

The nucleic acids of many plant viruses encode proteins with one or more of the following properties: an Mr of approximately 30,000, localization in the cell wall of the infected plant and a demonstrated role in cell-to-cell transport of infection. A progressive alignment strategy, aligning first those sequences known to be similar, and then aligning the resulting groups of sequences, was used to examine further the relatedness of the amino acid sequences of putative transport proteins of caulimoviruses, of proteins similar to the putative transport protein of alfalfa mosaic virus (A1MV) and of those similar to the tobacco mosaic virus (TMV) 30K protein. The strategy first identified regions in which multiple dipeptides of one group were similar to those of another group. The regions of similarity were brought into alignment by the conservative introduction of gaps. The positions of the introduction of gaps were adjusted to optimize similarity. Statistical significances of the resulting alignments, determined both by comparison with shuffled amino acid sequences and with the sequence alignment off-set by 1 to 15 residues in each direction, suggest that the amino acid sequences of the three groups of viruses are distantly related. Nevertheless, significant relationships between members of the caulimoviral group of sequences and members of each of the A1MV-like and TMV-like groups were found. These relationships and the analysis of the number of insertions/deletions between present sequences and a hypothetical common ancestor suggest that the sequences of the caulimoviral proteins are less diverged from the ancestor than either the A1MV-like or TMV-like proteins. The alignment identified common regions of predicted secondary structure and regions of similar hydropathy, regions possibly crucial for proper functioning of the proteins.

A readable and space-efficient DNA sequence representation: application to caulimoviral DNAs

A new representation of nucleotide sequence information has been devised to allow the clear presentation of large amounts of sequence information in a limited amount of space. Nucleotide sequences of DNA are represented by squares in three vertically aligned positions for each nucleotide. The squares represent, from top to bottom: a purine, a guanine or cytosine and a pyrimidine. The representation provides a simultaneous representation of both strands of double-stranded DNA and can be easily scanned visually for a variety of sequence features. Biologically important features of the DNA sequence near the origin of SV40 replication are easily recognized. The representation was also used to identify possibly base-paired stems in caulimoviral transcripts that may be of significance for viral replication.

Replication of cauliflower mosaic virus DNA in leaves and suspension culture protoplasts of cotton

Cauliflower mosaic virus (CaMV) replicated in protoplasts and in inoculated leaves of the non-host, cotton (Gossypium hirsutum, L.). Protoplasts prepared from suspension-cultured cotton cells were infected by incubation with liposome-encapsulated CaMV virions. During a 1-week culture period the amount of CaMV nucleic acid as detected by nucleic acid hybridization in the protoplasts increased significantly regardless of whether or not the protoplasts contained vacuoles. In leaves inoculated with CaMV virions or CaMV DNA, viral DNA sequences were found by leaf skeleton hybridization to be located in small circular areas. DNA extracted from ultracentrifugal pellets of homogenates of inoculated leaves contained circular, gapped CaMV DNA only when inocula contained CaMV virions, CaMV DNA, or partial nested dimer CaMV plasmid DNA. When plants had been heavily watered, the CaMV DNA recovered contained degraded CaMV DNA. The results suggest that the host range limitation for CaMV is not due to an inability to replicate or spread locally in inoculated leaves.

Infectious and non-infectious mutants of cauliflower mosaic virus DNA

Mutants of cauliflower mosaic virus (CaMV), generated in vitro by modification of recombinant DNA plasmids containing the viral genome, either retained the ability to induce disease symptoms on turnip plants, produced less severe symptoms or failed to induce symptoms. Wild-type symptoms were produced by a variant CaMV DNA of the Cabbage S isolate that had 4 bp in open reading frame (ORF) III replaced with a 16 bp sequence. Less severe symptoms, due to a delay in symptom appearance relative to inoculation with wild-type DNA, were induced by a mutant with a frameshift mutation in ORF II (pSA103). CaMV DNA, recovered from plants infected with pSA103, contained a second mutation which restored the original translation reading frame. Nucleic acid hybridization to 'squishes' of leaf tissue from plants that had been inoculated with mutant DNAs that included DNAs modified in each of the six major ORFs of CaMV DNA revealed that only those plants that appeared diseased had detectable CaMV nucleic acid in uninoculated leaves. Replicated CaMV DNA was also not detected in non-encapsidated and virion DNA fractions from inoculated leaves of non-diseased plants.

Recombination between mutant cauliflower mosaic virus DNAs

A class of mutants of cauliflower mosaic virus (CaMV) DNA was distinguished based on its members' ability to induce symptoms when coinoculated on plants with other CaMV DNAs mutant at a different locus. Three mutants, one each in open reading frame I, III, and VI had this ability. A second class of mutant DNAs did not induce symptoms unless combined with a mutant DNA of the first class. Viral DNA extracted from diseased plants was shown by restriction enzyme digestion to have lost the mutant alleles. When turnip plants were inoculated with a recombining mutant derived from DNA of the Cabbage S isolate and a mutant derived from DNA of a different isolate, a heterogeneity in the viral DNA extracted from the diseased plants was detected by restriction enzyme analysis. Restriction analysis of cloned representatives of this heterogeneous population revealed regions consistent with repair of heteroduplexes formed during general recombination between duplex DNAs. Some regions consistent with this mechanism or with recombination by strandswitching during reverse transcription were found.

Infection of evacuolated turnip protoplasts with liposome-packaged cauliflower mosaic virus

The infectivity of reverse phase evaporation (REV) liposome-encapsidated cauliflower mosaic virus (CaMV) to turnip protoplasts was tested. The uptake of neutral or negative liposomes was stimulated by polyethylene glycol (PEG), while high levels of uptake of positive liposomes were obtained both in the absence and presence of PEG. The delivery of the vesicle contents to the protoplasts paralleled the uptake of liposomes. CaMV delivered to turnip protoplasts was degraded during the early period of culture. No increase in the amount of CaMV DNA could be detected on longer periods of culture. In contrast, when protoplasts were evacuolated prior to addition of REV liposomes, an increase in the amount of CaMV DNA was noted after some initial degradation of the input DNA.

Complementary DNA-25S ribosomal RNA hybridization: an improved method for phylogenetic studies

In a new combination of techniques for ribosomal RNA hybridization, complementary DNA is synthesized on 25S ribosomal RNA fragments generated by mild alkali treatment, by the enzymatic addition of polyadenylic acid tails, hybridization of these tails with oligo deoxyribosylthymine, and reverse transcription in the presence of tritiated TTP. Hybridization reactions are performed in solution. Heteroduplexes are collected on diethylaminoethylcellulose filter discs after treatment with S1 nuclease. The problems presented by secondary rRNA structure are avoided by denaturation before reverse transcription and before hybridization. The high percentage of duplex formation (78-87%), the low standard deviation of relative binding (averaging +/- 1.30% relative binding), and small differences in reciprocal hybridizations (1.71-5.18% relative binding), as well as the elimination of complications resulting from differences in the number of rRNA cistrons in nuclear DNA, make this method preferable to the membrane-filter technique commonly used in phylogenetic classifications based on the homology of large rRNAs.

Clones of cauliflower mosaic virus identified by molecular hybridization in turnip leaves

Mechanical inoculation of turnip leaves with cauliflower mosaic virus (CaMV) results after one to two weeks in the appearance on these leaves of local lesions. Local lesions were detected by hybridization of radioactive CaMV DNA with nucleic acid immobilized in leaf skeletons by solvent extraction, proteinase digestion, and alkali treatment. The pattern of lesions detected as dark circles on autoradiographs of the washed leaf skeletons was the same as that detected by staining of solvent-extracted leaves for starch. Starch lesions appeared as white areas against a dark purple back-ground. These lesions were first detected between 5 and 8 days after inoculation and grew in size until 10 days after inoculation. Lesions were also detected by staining solvent-extracted and proteinase digested leaves with ethidium bromide. The lesions appeared as dark areas in a bright fluorescent background, and were found in the same positions as the starch lesions.

Density comparisons of heavy chains of membrane and secreted immunoglobulins of mouse

In order to explore structural differences between membrane and secreted immunoglobulins the buoyant densities of mouse immunoglobulin (Ig) heavy (H) chains were compared by isopycnic centrifugation in CsCl containing guanidine hydrochloride. The buoyant densities, under denaturing conditions, of mouse myeloma protein MOPC 21 IgG, MOPC 315 IgA and MOPC 104E IgM H chains were consistent with their carbohydrate contents. Mouse membrane IgM and MOPC 104E-secreted IgM H chains were of equal density. The buoyant densities of MOPC 104E-secreted IgM and spleen-cell-secreted IgM H chains were indistinguishable. The IgD-like membrane H chain was denser than membrane IgM H chain, and its carbohydrate content was calculated to be 15.5%. The resolution of the technique was sufficient to conclude that the apparent 1500 mol.wt. difference, as determined by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, between membrane and secreted IgM H chains was due to peptide rather than to carbohydrate. The results also imply that intact membrane IgM and IgD bind detergent and are thus integral membrane proteins.