Serological classification of spiroplasmas: current status

Data concerning serological classification of spiroplasmas are in good agreement, but slightly different numerical designations have been given to existing groups. It is proposed that a standardized system be adopted based on information developed mainly by the IRPCM working team on spiroplasmas. The type species (Spiroplasma citri) should be redefined to include only the agent of citrus stubborn disease (subgroup I-1). Six other subgroups, including three proposed by Bové et al. in this volume (I-5, I-6, and I-7), are members of the Group I complex. Because subgroups I-1, I-2, and I-3 (1) show significant reciprocal differences in DNA-DNA homology and two-dimensional electrophoretic protein profiles, (2) occupy exclusive habitats, (3) are each associated with important diseases, and (4) consist of clusters of very similar or identical strains, it is suggested that Latin binomials could be assigned to subgroups I-2 and I-3. It is proposed that those criteria could serve as general guidelines for consideration of subgroups for species status in the class Mollicutes. The I-4 subgroup is assigned an uncertain status, pending comparisons with the LB-12 (I-5), M55 (I-6), and N525 (I-7) subgroups. To previously described serogroups we add the CN-5 Cotinus beetle spiroplasma (IX), the AES-1 mosquito strain (X), and the MQ-4 Monobia strain (XI).     

Spiralin: Major membrane protein specific for subgroup I-1 Spiroplasmas

Preparations of spiralin from membranes ofSpiroplasma citri, strain C189, purified by sequential solubilization with detergents followed by agarose-suspension electrophoresis induced rabbit antibodies that were largely specific forSpiroplasma citri Group I-1 spiroplasmas, as demonstrated by metabolic inhibition (MI), growth inhibition (GI), and deformation (DF) tests. By contrast, antibodies againstS. citri whole-membrane protein preparations reacted broadly with representative type cultures of seven subgroups of theS. citri complex. Neither antimembrane nor antispiralin sera reacted withS. floricola, S. mirum, or Group IV, (VI), (VII), or (VIII) spiroplasmas. Minor cross-reactions in MI and DF tests between antispiralin serum and Subgroup I-2 and I-3 antigens may have represented shared epitopes in a set of homologous membrane proteins of the three spiroplasmas, or antibodies against highly antigenic traces of other common membrane proteins in the purified spiralin preparations. The unique antigenic properties of spiralin, the most abundant protein in theS. citri membrane, explain in part the unique profiles shown by this spiroplasma species in comparative taxonomic serological tests.     

Temperature Ranges,Growth Optima,and Growth Rates of Spiroplasma (Spiroplasmataceae,class Mollicutes) Species

A new method was developed for determination of the doubling times of spiroplasmas. In this procedure, the time required for medium acidification of tubes in tenfold dilution series was recorded. Sixty-four spiroplasma strains, representing 24 groups and 11 subgroups, were studied. Eight strains representing putative new groups were also included in the study. Doubling times at 5, 10, 15, 20, 25, 30, 32, 37, 41, and 43°C were determined. The range of temperatures for spiroplasma growth was 5°–41°C. Twenty-three spiroplasmas had optima of 30°C, 29 had optima of 32°C, and 13 had optima of 37°C. The fastest growing spiroplasma was the MQ-4 strain (group XI), with a doubling time at optimal temperature of 0.6 h. The slowest was the Jamaican corn stunt strain B655 (subgroup I-3), with an optimal doubling time of 36.7 h. Spiroplasma strain B31 (group IV) had the widest range (5°–41°C), while the DW-1 strain and some subgroup I-3 strains had the narrowest, growing only at 25° and 30°C. Some spiroplasmas grew well at 41°C, but none grew at 43°C. The ability of spiroplasmas to withstand a wide range of temperatures may reflect the conditions to which they are exposed in nature, including the temperatures of the insect, tick, and/or plant hosts in which they are carried and the plant surfaces from which they may be acquired by arthropods.     

Spiroplasmas: serological grouping of strains associated with plants and insects.

Spiroplasma strains from plant and arthropod hosts, and from surfaces of flowers, were classified into three serological groups (designated I, II, and III) based on results from growth-inhibition tests. No significant cross reactions were observed among groups. The groupings were confirmed by ring-interface precipitin and microprecipitin tests, using membrane preparations as test antigens, and by organism-deformation tests. Serogroup I contained three subgroups: subgroup A (Spiroplasma citri strains Maroc R8A2 and C189), subgroup B (strain AS 576 and closely related strains from honeybee or flowers), and subgroup C (corn stunt spiroplasma strains). Serogroup II contained strains 23-6 and 27-31 isolated from flowers of the tulip tree (Liriodendron tulipifera L.) growing in Maryland. Serogroup III contained strains SR 3 and SR 9 isolated from flowers of the tulip growing in Connecticut. The subgroups of serogroup I were based on organism deformation, microprecipitin, and ring-interface precipitin tests. The data are consistent with the hypothesis that the three serogroups represent no less than three distinct spiroplasma species.     

Characterization and taxonomic status of tick spiroplasmas: a review

Three serologically distinct groups of spiroplasmas have been recovered from ticks. Spiroplasma mirum strains (from rabbit ticks, Haemaphysalis leporispalustris) and Y32 group (VI) spiroplasmas (from Ixodes pacificus) are the only spiroplasmas to have a clear association with these arthropods. Group (VI) spiroplasmas are distinguished by an unusual nonhelical morphology and their capacity to hemadsorb guinea pig erythrocytes. S. mirum strains are unique in their ability to induce cataracts or lethal brain infections in a number of young vertebrates and in their virulence for the chick embryo. The 277F spiroplasma, while initially recovered from a pool of rabbit ticks (H. leporispalustris), is related by certain serological and genetic properties to spiroplasmas in the S. citri complex (serogroup I). These relationships suggest that the 277F spiroplasma may not be a natural inhabitant of the rabbit tick.     

Deoxyribonucleic acid hybridization betweenSpiroplasma citri and the corn stunt spiroplasma

The DNA base composition of the R8-A2 strain ofSpiroplasma citri and the I-747 and E strains of corn stunt spiroplasma was determined, by using the thermal denaturation temperature (T _m ), to be 26.8, 26.3, and 26.0 mol% (G+C), respectively. By the simple hybridization method, a measurement of the relative binding of homologous or heterologous labeled DNA to unlabeled, DNA-immobilized, nitrocellulose membrane, a homology of 56–60% was demonstrated betweenS. citri and two strains of corn stunt spiroplasma. A relatively higher DNA homology (66–71% between these two organisms was obtained in teh competition experiment, a measurement of the relative ability of homologous or heterologous competitor DNA to block the formation of homologous DNA-DNA duplex.     

Wall-less prokaryotes from fall flowers in central United States and Maryland

Four spiroplasma strains and eleven isolates tentatively identified as acholeplasmas were obtained from fall flowers in Colorado, Nebraska, Illinois, and Maryland. Although the acholeplasma isolates were heterogeneous, all showed antigenic sharing with a group of unnamed organisms (L1 and related strains) isolated in othe studies from flowers in Florida. The W20 and W24 isolates from Nebraska were partially related to the L1 group by DNA-DNA homology and polyacrylamide gel electrophoresis (PAGE) analyses. A Colorado spiroplasma (W13) was identifed as a new strain of group IV complex. Three spiroplasma strains from flowers in Maryland old fields represent a new serovar with closest affinity to subgroup I-4 and to the LB12 and N525 serovars of group I. Widespread occurrence of acholeplasmas on flowers in this study, and on plant surfaces in general, suggests that, like spiroplasmas they probably will be found to reside in arthropods.     

Phylogenetic analysis of saccharolytic oral treponemes isolated from human subgingival plaque.

A total of 74 strains of oral treponemes, which were isolated from subgingival plaque samples from patients with periodontitis, were taxonomically studied on the basis of biochemical characteristics, DNA-DNA hybridization, and 16S rRNA gene sequences. These organisms fermented carbohydrates and required rumen fluid or short-chain volatile fatty acids for growth. The isolates were divided into seven subgroups based on their biochemical characteristics. The levels of DNA relatedness among the representative strains of each subgroup and Treponema socranskii (including three subspecies) were greater than 78%, while the levels of DNA relatedness among these strains and other Treponema species, including T. denticola and "T. vincentii", were less than 15%. DNA-DNA hybridization indicated that all subgroups belonged to T. socranskii. This result correlated well with the cluster on the phylogenetic trees based on 16S rRNA sequences.     

胡枝了属根瘤菌的多相分类研究

采用数值分类,全细胞可溶性蛋白电泳分析,ＤＮＡ,Ｇ＋Ｃｍｏｌ％和ＤＮＡ相关性的测定以及１６ＳｒＤＮＡＰＣＲ－ＲＦＬ分析等多相分类技术对来源于不同地区的１６种寄主的胡枝子根瘤菌进行了系统的分类研究,数值分类的结果表明,在６７％的相似性水平上,全部供试菌可以为快生型根瘤菌和慢性型根瘤菌两大群,在８０％的相似性水平上又可分为两个亚群。在此基础上,对各亚群的胡枝子根瘤菌进行了ＤＮＡ相关性的测定,以进一步证     

Identity of cactus and lettuce spiroplasmas withSpiroplasma citri as determined by DNA-DNA hybridization

The isolation of spiroplasma strains from the cactusOpuntia tuna monstrosa and from aster yellows-diseased lettuce is described. DNA from these strains (ATCC 29594 and ATCC 29747) is compared with DNA fromSpiroplasma citri, and from the corn stunt and suckling mouse cataract spiroplasmas. The cactus and the lettuce isolates are found to be identical withS. citri by this method.     

Chemically Defined Medium for Cultivation of Several Epiphytic and Phytopathogenic Spiroplasmas

A chemically defined medium, LD82, was formulated for in vitro cultivation of spiroplasmas. Medium LD82 supported good growth for four epiphytic and insect-pathogenic spiroplasmas, Spiroplasma floricola 23-6^T, Spiroplasma sp. strain SR3, Spiroplasma sp. strain brevi, and Spiroplasma sp. strain AS576, and of the phytopathogenic spiroplasmas Spiroplasma citri Maroc R8A2^T and PC1. Titers of all six strains grown in defined medium LD82 reached 2.0 × 10⁹ to 6.0 × 10⁹ CFU/ml of culture. All spiroplasma strains tested formed colonies readily on agar medium LD82. None of the spiroplasmas formed typical fried-egg colonies. All formed diffuse colonies, but the forms of colonies differed somewhat among the spiroplasma strains. In preliminary studies of nutritional requirements, phospholipids slightly enhanced the growth of the epiphytic and insect-pathogenic strains in medium LD82 and were found essential for good growth of S. citri.     

Nutritional requirements of two flower spiroplasmas and honeybee spiroplasma.

A chemically defined medium (CC-494) was used to study the nutritional requirements of three spiroplasmas representing three distinct serogroups: flower spiroplasmas [Spiroplasma floricola and FS (SR-3)] and honeybee spiroplasma [HBS (AS-576)]. Glucose, fructose, and mannose were utilized by all three spiroplasmas. In addition, the honeybee spiroplasma could ferment trehalose, FS (SR-3) could ferment sucrose, and S. floricola could ferment trehalose, sucrose, and raffinose. The three spiroplasmas varied greatly in their requirements of amino acids for growth. S. floricola was the only strain that utilized arginine. HBS (AS-576) required at least one purine and one pyrimidine base (either free base or ribonucleoside) for growth, while both flower spiroplasmas grew with only one base in the medium. Oleic acid, cholesterol, and bovine serum albumin were essential to all three spiroplasmas. Palmitic acid, which was nonessential, promoted growth significantly.     

Spiroplasma membrane lipids.

Membranes of six spiroplasma strains belonging to different Spiroplasma species and subgroups were isolated by a combination of osmotic lysis and sonication in the presence of EDTA to block endogenous phospholipase activity. Analysis of membrane lipids showed that in addition to free and esterified cholesterol the spiroplasmas incorporated exogenous phospholipids from the growth medium. Sphingomyelin was preferentially incorporated from phosphatidylcholine-sphingomyelin vesicles or from the serum used to supplement the growth medium. Palmitate was incorporated better than oleate into membrane lipids synthesized by the organisms during growth. The major phospholipid synthesized by the spiroplasmas was phosphatidylglycerol. The positional distribution of the fatty acids in phosphatidylglycerol of Spiroplasma floricola resembled that found in Mycoplasma species, in which the saturated fatty acids prefer position 2 in the glycerol backbone and not position 1 as found in Acholeplasma species and elsewhere in nature. Electron paramagnetic resonance analysis of spin-labeled fatty acids incorporated into S. floricola membranes exhibited homogeneous single-component spectra without immobilized regions. The S. floricola membranes were more rigid than those of Acholeplasma laidlawii and less rigid than those of Mycoplasma gallisepticum.     

DNA probes in detection of spiroplasmas and mycoplasma-like organisms in plants and insects

Abstract DNA probes were applied to detect spiroplasmas and uncultivable mycoplasma-like organisms (MLOs) in infected plants and insects. The probes consisted of pMC5, a plasmid carrying the RNA genes of Mycoplasma capricolum and pRA1, a plasmid recovered from Spiroplasma citri . Southern blot hybridization of pMC5 with digested DNAs of periwinkle plants infected with S. citri , or with various MLOs, yielded 2 heavy and several weaker bands. The heavy hybridization bands were shown to represent rRNA genes of the plant chloroplasts, indicating significant nucleotide sequence homology between the mycoplasmal rRNA genes and those of plant chloroplasts. Some of the weaker hybridization bands, not revealed in DNA of healthy plants, appeared to represent rRNA gene sequences of the infectious agent. Use of the spiroplasma plasmid as a probe enabled the detection of S. citri in infected plant material and in hemolymph of infected leafhoppers at a high sensitivity level.     

Antibiotic sensitivities in vitro of diverse spiroplasma strains associated with plants and insects

Fifteen spiroplasma strains, representing five serological subgroups classified in three distinct serogroups, and four strains unassigned to serogroups were examined for sensitivity to antibiotics. The data contribute to the characterization of spiroplasmas and enlarge comparisons between plant pathogenic strains and strains that are evidently a part of the normal epiphytic microflora.     

Powder puff spiroplasma: A new epiphytic mycoplasma

A spiroplasma (strain PPS1) isolated from healthy flowers ofCalliandra haematocephala in Florida has been found to be a member of a serogroup of the Spiroplasmataceae. It is distinct fromSpiroplasma citri and from other described spiroplasmas as determined by growth inhibition, fluorescent antibody, and ELISA serological tests. PPS1 was also distinguished fromS. citri and several other spiroplasmas by the guanine + cytosine content of its DNA. PPS1 requires sterol for growth, is inhibited by digitonin, grows at 20–30°C, and does not hydrolyze arginine or urea. The ready isolation of this and similar organisms from surfaces of healthy plants emphasizes that caution should be exercised in attempts to isolate cell wall-less prokaryotes from the interior of diseased plants. Although some strains of spiroplasmas are known as insect pathogens in nature, the ecological role(s) of the flower-inhabiting spiroplasmas has yet to be fully determined.     

Vitamin requirements of three spiroplasmas.

A chemically defined medium (CC-494M) was used to study the vitamin requirements of three spiroplasmas representing three distinct serogroups: flower spiroplasmas [Spiroplasma floricola and FS (SR-3)] and honeybee spiroplasma [HBS (AS-576)]. Nicotinic acid and riboflavin were essential to spiroplasma growth. Nicotinamide could substitute for nicotinic acid. Populations of S. floricola, FS (SR-3), and HBS (AS-576) reached 3.2 X 10(9), 1.96 X 10(10), and 6.1 X 10(9) CFU/ml, respectively, when nicotinic acid (0.036 mg/liter) and riboflavin (0.014 mg/liter) were supplied.     

Spiroplasma Species, Groups, and Subgroups from North American Tabanidae

Twenty-one triply cloned spiroplasma strains from the United States east of the Rocky Mountains, all isolated from tabanid (Diptera:Tabanidae) flies or serologically related to strains from tabanids, were compared reciprocally by spiroplasma deformation (DF) and metabolism inhibition (MI) serological tests. Many of the strains were also tested against 28 antisera representing known spiroplasma groups, subgroups, and putative groups isolated from nontabanid hosts. Relationships among strains were indicated by reciprocal cross-reactivity in both DF and MI tests. The strains were found to represent 11 recognized spiroplasma groups or subgroups. On the basis of serological, biochemical, and genomic data, strain BARC 1901 from Tabanus lineola appeared to represent a previously unrecognized candidate group. Strain BARC 2649, also from T. lineola, also appeared to represent a new group, but its morphology, arginine utilization, and some one-way serological crossing patterns suggested that it may be distantly related to group VIII spiroplasmas. Morphological, serological, and genomic data were used to place tabanid spiroplasma strains into three informal clusters. These are (i) groups IV (strain B31) and XXXI (strain HYOS-1); (ii) the three existing subgroups and a new candidate subgroup of group VIII represented by strain BARC 1357 plus ungrouped strain BARC 2649; and (iii) 14 strains, including EC-1 and TATS-1 (group XIV); strains TN-1 and TAAS-2 (group XVIII); strains TG-1, TASS-1, and BARC 4689 (group XXIII), strains TALS-2 (group XXVII), strain TABS-2 (group XXXII), and strains TAUS-1 and TABS-1 (group XXXIII) and ungrouped but closely related strains BARC 1901, BARC 2264 and BARC 2555. Analysis of tabanids from other geographic regions probably will substantially increase the number of known spiroplasma groups from this insect family. Received: 23 April 1997 / Accepted: 31 May 1997     

Differentiation of group VIII Spiroplasma strains with sequences of the 16S-23S rDNA intergenic spacer region

Spiroplasma species (Mollicutes: Spiroplasmataceae) are associated with a wide variety of insects, and serology has classified this genus into 34 groups, 3 with subgroups. The 16S rRNA gene has been used for phylogenetic analysis of spiroplasmas, but this approach is uninformative for group VIII because the serologically distinct subgroups generally have similarity coefficients >0.990. Therefore, we investigated the utility of the 16S-23S rRNA spacer region as a means to differentiate closely related subgroups or strains. We generated intergenic sequences and detailed serological profiles for 8 group VIII Spiroplasma strains. Sequence analyses using Maximum Parsimony, Neighbor Joining, and Maximum Likelihood placed the strains into 2 clades. One clade consisted of strains BARC 2649 and GSU5367. The other clade was divided into clusters containing representatives of the 3 designated group VIII subgroups (EA-1, DF-1, and TAAS-1) and 3 previously unclassified strains. The stability of the positions of the strains in various analytical models and the ability to provide robust support for groupings tentatively supported by serology indicates that the 16S-23S intergenic rDNA sequence will prove useful in intragroup analysis of group VIII spiroplasmas.