Antigenic diversity is generated in the wall‐less pathogen Mycoplasma hyorhinis by combinatorial expression and phase variation of multiple, size‐variant membrane surface lipoproteins (Vlps). The unusual structural basis for Vlp variation was revealed in a cluster of related but divergent vlp genes, vlpA, vlpB and vlpC, which occur as single chromosomal copies. These encode conserved N‐terminal domains for membrane insertion and lipoprotein processing, but divergent external domains undergoing size variation by loss or gain of repetitive intragenic coding sequences while retaining a motif with distinctive charge distribution. Genetic analysis of phenotypically switched isogenic lineages representing ON or OFF expression states of Vlp products ruled out chromosomal rearrangement or frameshift mutations as mechanisms for Vlp phase variation. However, highly conserved vlp promoter regions contain a tract of contiguous A residues immediately upstream of the −10 box which is subject to frequent mutations altering its length in exact correspondence with the ON and OFF phase states of specific genes. This suggests a mechanism of transcriptional control regulating high frequency phase variation and random combinatorial expression of Vlps. The multiple levels of diversity embodied in the vlp gene cluster represents a novel adaptive capability particularly suited for this class of wall‐less microbe.
Variable lipoproteins (Vlp) constitute the major coat protein of Mycoplasma hyorhinis. They are products of multiple, divergent, single-copy genes organized in a chromosomal cluster. Three genes, vlpA, vlpB, and vlpC, have been previously identified in clonal isolates of M. hyorhinis SK76. Each is linked to a characteristic promoter region containing a homopolymeric tract of adenine residues [poly(A) tract], subject to hypermutation, that transcriptionally controls phase variation of vlp genes and leads to combinatorial surface mosaics of distinct Vlp products. The size of the natural vlp gene repertoire is unknown but may critically determine the degree of structural and combinatorial diversity available in this species. In this study, the vlp repertoire of M. hyorhinis GDL-1 was characterized and shown to contain three additional genes, vlpD, vlpE, and vlpF, clustered with other known vlp genes in the order 5-vlpD-vlpE-vlpF-IS-vlpA-IS-vlpB-vlpC-3, where IS represents copies of the IS1221 element of M. hyorhinis. The 5 boundary of this expanded family was identical to that of the more limited family 5-vlpA-IS-vlpB-vlpC-3 previously described in a clonal isolate of strain SK76. A recombinant construct containing vlpD, vlpE, and vlpF expressed antigenically distinguishable products corresponding to each gene. These genes encode characteristic C-terminal repetitive regions that are subject to size variation by insertion or deletion of intragenic repeats but maintain an extended, charged structure. Each vlp gene also contained characteristic alternative open reading frames, which provide a potential reservoir of coding sequence for Vlp diversity, possibly recruited through insertion and/or deletion mutations. These findings demonstrate a vastly expanded potential for structural diversity and combinatorial display of surface mosaics on this organism and suggest that modulation of the vlp repertoire, possibly in conjunction with mobile elements, may determine the capacity for surface variation in natural populations and laboratory strains of this mycoplasma species.The variable lipoprotein (Vlp) system of Mycoplasma hyorhinis provides a mutational strategy for adaptive surface variation that generates extreme population diversity in the major coat proteins expressed on this wall-less procaryote (27,28,38,40). The complexity of this system and its role as a prototype for analogous emerging systems in other mycoplasma species warrants a detailed characterization of the genetic and structural attributes contributing to its adaptive capabilities. Vlps are procaryotic lipoproteins processed by cleavage of a conserved prolipoprotein sequence (11) and expressed as abundant surface proteins anchored on the single mycoplasma membrane by a lipid moiety on an N-terminal Cys residue. Molecular genetic analysis has shown that alternative Vlps share distinctive structural features despite divergence throughout their surface-exposed protein sequence. Structural details of known Vlps (VlpA, VlpB, and VlpC) have been defined at the g...
A prototype family of seven genes encoding the variable surface lipoproteins (Vlps) of Mycoplasma hyorhinis is characterized in the pathogenic SK76 strain, using long-range PCR to amplify and analyze the single chromosomal region containing expressed genes vlpA to -G, each of which is subject to phase and size variation. Smaller families of vlp genes in subclones of SK76 or in another strain of M. hyorhinis, GDL, can be attributed to deletions of specific vlp genes from the prototype array described here. Two genes, vlpA and the newly revealed vlpG, contain repeat motifs in their 3 coding regions that differ from the short tandem repeats in other vlp genes yet retain structural features common to all vlp gene products. SK76 and GDL vlp gene families are similarly organized and show sequence similarity between corresponding individual vlp genes. In light of the extensive potential for diversity within the vlp gene system, such conservation provides a provisional basis to hypothesize that vlp genes may exist in specific arrays that endow selected functions while retaining common structural features required during phase-variable expression of this set of gene products.
Triton X-114 (TX-114)-phase fractionation was used to identify and characterize integral membrane surface proteins of the wall-less procaryote Mycoplasma hyorhinis GDL. Phase fractionation of mycoplasmas followed by analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed selective partitioning of approximately 30 [35S]methionine-labeled intrinsic membrane proteins into the TX-114 phase. Similar analysis of [3HJpalmitate-labeled cells showed that approximately 20 proteins of this organism were associated with lipid, all of which also efficiently partitioned as integral membrane components into the detergent phase.
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